BR112013012739B1 - AIR PURIFICATION SYSTEM - Google Patents

Abstract

air purification system. The systems and processes described in this specification are directed to an air purification system which can draw air from outside a structure and purify air to at least a level that is generally healthy for human inhalation. furthermore the air purification system may function to supply warmer or colder purified air within a structure. In addition, the air purification system may include an item for purifying air circulating into or into the interior space of a structure. The air purification system may also include a solar heating element which functions to increase the temperature of the purified air in the air purification system.

Description

AIR PURIFICATION SYSTEM

Reciprocal reference to related patent applications [001] This patent application claims priority benefit under Article 35 USC ξ 119 for provisional patent application No. 61 / 417,090, filed on November 24, 2010, entitled Air Purification System, the description of which is incorporated by reference in this specification.

Background [002] The air used in air conditioning structures (ie homes, buildings) can originate from the inside of a structure or from the outside of a structure. Some problems associated with the use of air from outside a structure, to condition air in the internal areas of a structure, include the introduction of contaminants and external particulate materials commonly found in external air. The outside air can contain smoke and fog, which can contain carbon monoxide, ozone and other pollutants, which can irritate people's respiratory systems. In addition, the introduction of mold spores and pollen, which are common particulate materials found in external air, can cause unwanted mold to grow inside and induce allergic reactions to people occupying the structure. In addition to contaminated air, which can be placed in a building outside, air contaminants can leak from a basement (for example, through a low space) and accumulate in common areas occupied by people. Air escaping from a basement can carry mold spores and potentially harmful gases, such as radon, which can present health risks for those occupying the structure.

[003] Furthermore, most structures generally breathe, due, at least in part, to variations in external air pressure relative to air pressures within the structures. For example, when the air pressure outside a structure is greater than the air pressure inside a structure, the outside air tends to leak into the structure. When the air pressure outside a structure is lower than the air pressure inside a structure, the air inside the structure tends to leak out of the structure. Generally, the pressure differential between the outside of a structure and the inside of a structure can be caused by several factors (ie, atmospheric variations, wind, working exhaust fans, operating stoves and fireplaces, etc.). Continuous breathing of a structure can be essential to supply fresh oxygen to the occupants of a structure. However, if the leak

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2/11 of air to a structure is uncontrolled, the air introduced into a structure can carry contaminants and undesirable particulate materials, which can eventually be inhaled by occupants.

[004] Some conventional air purification systems, which are currently available, recirculate the air inside the structure, which prevents the purity of the indoor air from being affected, at least for the reasons described above. In addition, some air purification systems expel harmful by-products, such as ozone, in the air from structures, as a result of their air purification processes. Ozone is a harmful air pollutant, which can be harmful to breathing, and long-term exposure to ozone can permanently reduce people's breathing capacity. In particular, children, the elderly and people with respiratory diseases may be especially sensitive to ozone inhalation. Therefore, at least for the reasons described above, there is a need for an air purification system, which can supply purified air to the internal part of a structure, without expelling harmful levels of ozone in the structure.

[005] Details of one or more embodiments are presented in the attached drawings and in the description below. Other aspects and advantages will be evident from the description and drawings, and from the claims.

Summary [006] Some implementations of the air purification system include at least one housing. The housing can incorporate a mounting mechanism, to mount the air purification system on a structure. In addition, the housing may also include an air inlet and an air outlet. Furthermore, the air purification system can include a fan, which can be actuated by a control circuit. Additionally, the control circuit can control an air flow through the air purification system, by controlling the fan speed. The housing can also include at least one filter, positioned inside it, and an ultraviolet light source, mounted inside it. In addition, at least one photocatalytic element can be positioned adjacent to the ultraviolet light source, so that the air, which passes through the air purification system, is exposed to the photocatalytic element and the ultraviolet light source. The housing can also include at least one chemical catalyst element, which is exposed to air, which passes through the air purification system.

[007] Details of one or more embodiments are shown in the descriptions

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3/11 annexed and in the description below. Other aspects and advantages will be evident from the description and drawings, and from the claims.

Brief description of the drawings [008] These and other aspects will be described below with reference to the drawings presented below.

[009] Figure 1 illustrates an embodiment of an air purification system.

[0010] Figure 2 illustrates a flow chart of a pressure differential function of the air purification system.

[0011] Figure 3 illustrates a flow chart of a heating function of the air purification system.

[0012] Figure 4 illustrates a flow chart of a cooling function of the air purification system.

[0013] Similar reference symbols in the various drawings indicate similar elements.

Detailed Description [0014] This document describes an air purification system, which is at least capable of pulling air out of a structure and purifying it to at least a level that is generally healthy for human inhalation. In addition, the air purification system can work to provide warmer or cooler purified air within a structure. In addition, the air purification system may include an item to purify air circulated within a structure. In alternative implementations, an air purification system can also include a solar heating element, which can work to increase the temperature of the purified air in the air purification system.

[0015] An air purification system is described in this specification, which includes items that allow it to be integrated into a structure and provide an air flow route between the exterior (ie, the external space) and the interior (that is, the internal space) of the structure. The air purification system can be coupled to an air duct or pipe, which is already part of the structure, so that the installation of the air purification system generally does not require additional holes or penetrations in any walls of the structure. Alternatively, generally any wall of a structure can be penetrated to adapt an air purification system to the structure. In general, the air purification system

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4/11 can be integrated into a structure, so that it can purify air, as it is forced from outside the structure into its internal area, as will be discussed in more detail below.

[0016] Now returning to the figures, Figure 1 shows an implementation of the air purification system 100. The air purification system 100 may include a housing 102, which generally houses the components of the air purification system 100. The housing 102 can be formed of one or more parts and can include items (i.e., mounting holes, fasteners, etc.), which can assist in securing the placement of the air purification system 100 in a structure. In addition, housing 102 of air purification system 100 can accommodate a fan 104, which, when in circulation, forces air to pass through air purification system 100. For example, a fan 104 in housing 102 it is willing to pull air out of a structure, force it through the air purification system 100, and expel the freshly purified air into the structure. The fan 104 may be a variable speed fan, so that the flow at which air is passed through the air purification system 100 can be varied. The rotation speed of the fan 104 can be controlled manually by a user, or programmed, as will be discussed in more detail below. Although described in the present specification as a fan, several mechanisms can be used to force air through the air purification system 100, without departing from the scope of the present invention.

[0017] In general, if all devices that admit air in the building (ie windows, doors, etc.) are closed and the air purification system 100 is providing an adequate air flow to the outside structure, the air purification system 100 can essentially become as the only external air source for the structure. Therefore, the air purification system 100 can not only generally provide the only external air source for a structure, but can also create and maintain a pressure differential between the internal and external parts of the structure. For example, insofar as the air purification system 100 forces air from outside a structure and expels it inside a structure, the air purification system 100 can basically cause a greater pressure than outside the structure. The capacity of the air purification system 100 to create and maintain this pressure differential generally limits any air entering the structure from the outside, either through the air conditioning system alone.

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5/11 air purification 100. Therefore, the remaining air leaks through the structure, which can otherwise be a source of contaminants entering the building, is generally limited to air leaving the building. By limiting the source of airflow in the structure to being only by the air purification system 100, the reduction in external contaminants (ie mold spores, pollen, dust, smoke, etc.) entering the interior of the structure it may become even smaller, due to the ability of the air purification system 100 to eradicate air contaminants, as the air is passed through the air purification system 100, as will be described in more detail below. Basically, this can help to reduce allergic reactions, respiratory irritations and other health problems associated with exposure to air contaminants to these people occupying the structure.

[0018] The air purification system 100 can be designed, sized and energized so that it can adequately maintain clean air within an area of a structure. For example, the air purification system 100 can handle 0.5 air changes per hour, which is generally known as the air exchange rate (AER) required to continuously ventilate a home under humid conditions. However, the air purification system 100 can be designed and energized to effectively maintain the cleanest air in various elaborated and dimensioned structures, without departing from the scope of the present invention.

[0019] The air purification system 100 includes an air purification technology, which reduces, if not eliminates, the release of ozone to the internal area of the structure, in which purified air is provided. Ozone can cause health problems, including irritation to the respiratory system and breathing difficulties. Therefore, the air purification system is configured to significantly reduce, if not prevent, the release of ozone within the structure, due to any air purification process, as will be discussed below.

[0020] As illustrated in Figure 1, the air purification system 100 includes one or more of a filter 106, a photocatalytic element 108, an ultraviolet (UV) light source 110, a reflective material 112 and a chemical catalyst element 114 In addition, and also shown in Figure 1, the air purification system 100 can also include a screen with blades 116 and a directional outlet 118. The air purification system 100 can be installed in a structure, so that the screen with blades 116 is generally in contact with the external air and the directional outlet 118 is generally in contact with the internal air of the structure. In this

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6/11 configuration, the fan 104 can work to draw air from outside and force it to pass through the screen equipped with blades 116, filter 106, photocatalytic element 108 and be exposed to UV light. After the air is exposed to the UV light source 110, the fan 104 can continue to force the air out through the chemical catalyst element 114 and directional outlet 116, before being expelled into a structure.

[0021] In general, the screen with blades 116 provides a directional air flow inlet for the air purification system 100. Additionally, the ventilation item of the screen with blades 116 will help to reduce the turbulence of the flow and minimize , if not prevented, direct UV light emissions from the air purification system 100. Once the air has passed through the screen equipped with blades 116, and the air is then forced by one or more filters 106, as shown in Figure 1 Generally, one or more filters 106 work to capture and eliminate various particulate materials carried from the air. In general, filters can work to generally capture larger particulate matter. However, several filters can be used, which are designed to capture various types and sizes of particulate materials, without departing from the scope of the present invention.

[0022] Once the air has passed through one or more filters 106, the air is then forced by the photocatalytic element 108 and exposed to the UV light source 110. For example, the photocatalytic element 108 can be comprised of a film photocatalyst thin, such as titanium dioxide, which is usually coated in an element that allows air to pass through it (ie, a screen with blades). Similar to the screen with blades 116 described above, vents can be used again in the present invention to minimize direct UV light emissions from the air purification system 100 and reduce airflow turbulence. The photocatalytic coating allows particulate materials, such as organic compounds, in the air to come in contact with the photocatalyst, so that they are destroyed by exposure to UV light. After the particulate materials have come in contact with the photocatalyst, the particulate materials are exposed to the UV 110 light source. As described above, the UV 110 light source activates the photocatalyst, to destroy the remaining particulate materials in the air. Reflective material 112 can surround at least part of the UV light source 110, and can work to increase the intensity of UV light and the exposure of UV light to particulate materials. The increased intensity and exposure of UV light to particulate materials can increase the efficiency in activating the photocatalyst and eradicate particulate materials from the air. In

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7/11 Overall, the combination of a photocatalyst and UV light can effectively eradicate any particulate materials remaining in the air that the filter was unable to remove. Various photocatalysts can be used to eliminate particulate materials from the air, without departing from the scope of the present invention.

[0023] After the air has been exposed to the UV light source, the air is forced beyond the fan 104 and by a chemical catalyst element 114, before being expelled through the directional outlet 118 and into the structure. The chemical catalyst element 114 can be a screen or filter, which is generally coated with a chemical catalyst. The chemical catalyst generally works to decompose ozone, which was formed as a by-product during the air purification process, conducted in the air purification system 100. As mentioned above, ozone can be harmful to people's health, so it is a benefit of the air purification system 100 is that it generally prevents the expulsion of ozone. For example, chemical catalysts, such as those including manganese dioxide, can be used to decompose ozone in the 100 air purification system. However, several chemical catalysts can be used to cause ozone to decompose, without moving away falls within the scope of the present invention.

[0024] In addition, the directional outlet 118 may include blades, which allow a user to direct the air discharge from the air purification system 100 inside the structure. In addition, and shown in Figure 1, the airflow passage can cause the directional outlet 118 to be designed and structured so that it is a generally cylindrical passage. A generally cylindrical air flow passage can promote laminar flow, which can basically provide a desirable in-line flow of the air purification system 100 into a structure. However, several molded air flow passages can be provided in the air purification system 100, which promote laminar flow through the air purification system 100, without departing from the scope of the invention.

[0025] The air purification system 100 can also include a control circuit, which can be contained within at least part of the housing 102. For example, the control circuit can be located in the part of the housing that is exposed to internal part of the structure. In addition, the control circuit can help to provide the air purification system with user-programmable aspects and functions, conveniently accessible to a user from within the structure. The circui

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The control circuit can control various components and electrically energized items within the air purification system 100. For example, the control circuit can control the speed of the fan 104, to produce a desired air flow through the air purification system. air 100. Additionally, the control circuit can allow the fan speed to be controlled manually by a user, or programmed to run at a certain speed or a range of it. In addition, the control circuit may include additional items that measure (ie pressure, temperature, etc.), and vary the speed of the fan 104 generally automatically according to the measurement made, as will be discussed in more detail. below.

[0026] For example, the control circuit can include pressure measurement elements, which can take pressure readings both inside and outside the structure. From these measurements, the control circuit can then either increase or decrease the fan speed, if necessary, to obtain a pressure differential value or a range of it between the internal and external parts of the structure. The pressure differential value or its range can be adjusted by a user, or it can be a pre-programmed setting embedded within the air purification system 100. The capacity of the air purification system 100, to monitor this pressure differential pressure, allows the air purification system 100 to respond efficiently to variations in pressure within the structure, just as a door is opened, without being based on a user.

[0027] Figure 2 is a flow chart of a process 120 for controlling an air purifier, according to some implementations. Process 120 can be used to determine the pressure differential between the internal and external parts of a structure, and consequently vary the fan speed. As shown in Figure 2, the internal pressure is measured at 122 and the external pressure is measured at 124. The internal and external pressures can be measured by one or more pressure measurement elements, such as a barometer or digital manometer. However, several pressure measurement elements can be employed by a pressure monitoring circuit of the air purification system 100, to measure at least the internal and external air pressures of a structure. For example, a pressure measurement element, used to measure the internal air pressure of a structure, can also be the same pressure measurement element, which measures the external air pressure of the structure. In 126, process 120

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9/11 also includes determining whether the measured internal air pressure is sufficiently greater than the measured external air pressure. If the measured internal pressure is sufficiently higher than the measured external pressure, the fan speed is generally not changed. However, if the internal air pressure is not sufficiently higher than the external air pressure, the fan speed is changed. At 128, it is determined whether the internal air pressure is too high. At 130, the fan speed is decreased if the internal air pressure is determined to be too high. At 132, the fan speed is increased if the internal air pressure is determined to be too low. As described above, an increase in fan speed increases the air expelled into the structure by the air purification system 100, which can eventually cause the pressure within the structure to increase relative to the outside of the structure.

[0028] In addition to purifying the air, the air purification system 100 can provide warmer or colder air to the structure, in relation to the air temperature inside the structure. For example, the control circuit can include temperature measurement elements (that is, thermistors, thermocouples, etc.), which can measure the internal and external air temperatures of a structure. From these measurements, the control circuit can then increase or decrease the fan speed, if necessary, to reach a defined temperature value, within the structure. The set temperature value, or a range thereof, can be adjusted manually by a user, or it can be a pre-programmed adjustment of the air purification system 100. The capacity of the air purification system 100, to monitor the temperature inside the structure, allows the air purification system 100 to respond efficiently to changes in temperature inside the structure, such as when a door is opened, without being based on a user.

[0029] Figure 3 is a flow chart of a process 140 for controlling the temperature inside a structure, using an air purification system, according to the implementations described in this specification. Process 140 can be used to determine the temperature within a structure and, consequently, vary the speed of the fan, to generally keep the internal air temperatures warm. As shown in Figure 3, the internal temperature is measured at 142. At 144, it is determined whether the internal temperature is at a certain value, or within a desired temperature range, which can be set by a user or pre-programmed . If the measured internal temperature is the temperature

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10/11 desired temperature, or within the desired temperature range, the fan speed is generally not changed. However, if the internal air temperature is not at the desired temperature, or within the desired temperature range, the fan speed is changed. At 146, the internal air temperature is determined to be very high. At 148, the fan speed is decreased if the internal air temperature is determined to be too high. At 150, the fan speed is increased if the internal air temperature is determined to be too low. In general, this heating function only works under conditions where the external temperature of the structure is higher than the internal temperature of the structure.

[0030] Figure 4 is a flow chart of a process 160 for controlling the temperature inside a structure, using an air purification system, according to the implementations described in this specification. Process 160 can be used to determine the temperature within a structure, and consequently vary the speed of the fan, to generally keep the internal air temperatures cool. As shown in Figure 4, the internal temperature is measured at 162. In 164, it is determined whether the internal temperature is at a desired temperature, or within a desired temperature range, which can be set by the user or pre-programmed. If the measured internal temperature is at the desired temperature, or within the desired temperature range, the fan speed is generally not changed. However, if the internal air temperature is not at the desired temperature, or within the desired temperature range, the fan speed is changed. In 166, it is determined whether the internal air temperature is too high. In 168, the fan speed is increased if the internal air temperature is determined to be too high. In 170, the fan speed is decreased if the internal air temperature is determined to be too low. Similar to the heating function described above, the cooling function generally only works under conditions in which the external temperature is lower than the internal temperature of the structure.

[0031] The air purification system, as described in this specification, can be configured with a solar heating element, so that it can work to increase the air temperature, at least before it is forced by the air conditioning system. air purification. In this configuration, the air purification system can provide heated air that has a higher temperature than

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11/11 that both the internal and external air temperatures of a structure. For example, the air purification system 100 can be installed in a south-facing part of a structure, which receives solar radiation during the winter period. In this configuration, solar radiation will fall on the south-facing wall in the northern hemisphere, usually only during the winter period, when heating the building is desired. Furthermore, the heating effect of the sun-irradiated wall can be enhanced by painting the wall in dark color and covering the wall with clear glass or plastic, to retain at least some solar energy between the covering and the wall. In addition, the air purification system 100 can include a solar cover, which can be placed adjacent to the air inlet, or a screen equipped with blades 116, to allow even more that the air purification system 100 expels air heated by the sun to the structure.

[0032] In addition, some implementations of the air purification system 100 may include a recirculation item, which can purify the air recirculated within the structure. This recirculation item may include an airflow circuit through the air purification system 100, which allows air within the structure to be drawn into the air purification system 100, and then expelled back into the structure, as purified air. In addition, the recirculation circuit can be partially or entirely closed at any time to allow partial or integral air recirculation within the structure. In particular, the recirculation item may be desirable, when there is a large temperature differential between the internal and external parts of the structure, or when the air outside is extremely polluted. In general, a user can manually activate the recirculation item, or the recirculation item can be activated automatically by the control circuit, in response, for example, to changes in external air temperature or air quality outside.

[0033] Although a few embodiments have been described in detail above, other modifications are possible. Other embodiments may be within the scope as shown below.

Claims (16)

1. Air purification system (100), FEATURED for comprising: at least one housing (102) having a mounting mechanism for mounting the air purification system (100) to a structure, the housing (102) also including a air inlet and air outlet; one or more pressure measurement elements are configured to measure air pressure outside a structure and within a structure; a fan (104) actuated by a control circuit, including one or more pressure measurement elements, the control circuit controlling an air flow through the air purification system (100) in response to air pressure measurements to maintain a predetermined pressure differential between the outside of the structure and the inside of the structure; at least one filter (106) positioned inside the housing (102); an ultraviolet light source (110) mounted inside the housing (102); at least one photocatalytic element (108) positioned adjacent to the source of ultraviolet light (110), so that the air passed through said air purification system (100) is exposed to the photocatalytic element (108) and the source of ultraviolet light ( 110); and at least one chemical catalyst element (114) exposed to the air that passes through the air purification system (100). 2. Air purification system (100) according to claim 1, CHARACTERIZED by the fact that the fan (104) is a variable speed fan. 3. Air purification system (100) according to claim 1, CHARACTERIZED by the fact that the control circuit is contained within at least part of at least one housing (102) and includes one or more measuring elements temperature. 4. Air purification system (100) according to claim 3, CHARACTERIZED by the fact that the one or more temperature measuring elements are capable of at least measuring the temperature outside a structure and within a structure. 5. Air purification system (100) according to claim 4, CHARACTERIZED by the fact that the control circuit is configured to vary the speed of rotation of the fan (104), in response to temperature measurementsPetition 870190015904, from 15 / 02/2019, p. 19/22 2/3 ra made by one or more temperature measurement elements. 6. Air purification system (100) according to claim 1, CHARACTERIZED by the fact that the control circuit is contained within at least part of the housing (102). 7. Air purification system (102) according to claim 1, CHARACTERIZED by the fact that a solar heating element is adapted to the air purification system (100). 8. Air purification system (100) according to claim 1, CHARACTERIZED by the fact that the air purification system includes an air flow path, which allows air within a structure to be recirculated by said system air purification system (100). 9. Air purification system (100), FEATURED for understanding: a housing (102) mounted on a wall of a structure, the housing (102) further including an air intake from an outdoor space of the structure, and an air outlet to an internal space of the structure; one or more pressure measurement elements integrated with the housing (102) and configured to measure air pressure outside a structure and within a structure; a fan (104) actuated by a control circuit, including one or more pressure measurement elements, the control circuit controlling an air flow through the air purification system, from the input to the output in response to the pressure measurements of air to maintain a predetermined pressure differential between the outside of the structure and the inside of the structure; a filter (106) inside the housing (102) near the entrance; a photocatalytic element (108) within the housing (102) adjacent to the filter (106); an ultraviolet light source (110) within the housing (102) adjacent to the photocatalytic element (106), so that air passing through the air purification system (100) is exposed to the photocatalytic element (108) and the light source ultraviolet (110); and at least one chemical catalyst element (114) within the housing (102) near the outlet, in which the system (100) supplies purified air directly to the internal part of the structure. Petition 870190015904, of 02/15/2019, p. 20/22 3/3 10. Air purification system (100) according to claim 9, CHARACTERIZED by the fact that the filter (106), the photocatalytic element (108) and the ultraviolet light source (110) are positioned inside the housing (102 ), within the outdoor space of the structure. 11. Air purification system (100) according to claim 9, CHARACTERIZED by the fact that the chemical catalyst (114) is positioned inside the housing (102), within the internal space of the structure. 12. Air purification system (100) according to claim 9, CHARACTERIZED by the fact that the fan (104) is a variable speed fan. 13. Air purification system (100) according to claim 9, CHARACTERIZED by the fact that the control circuit is contained within at least part of at least one housing (102) and includes one or more measuring elements temperature. Air purification system (100) according to claim 13, CHARACTERIZED by the fact that the one or more temperature measuring elements are capable of at least measuring the temperature outside a structure and within a structure. 15. Air purification system (100) according to claim 14, CHARACTERIZED by the fact that the control circuit is configured to vary the rotation speed of the fan (104), in response to temperature measurements made by the one or more temperature measurement elements. 16. Air purification system (100) according to claim 9, CHARACTERIZED by the fact that the control circuit is contained within at least part of the housing (102).