The present disclosure generally relates to a device and a system for gas injection in cavities of building structures (e.g., wall, floor and/or ceiling), particularly for drying, decontaminating or drying and decontaminating building structures. The present disclosure also generally relates to a system for monitoring parameters of a gas injection process using the device and system provided herein.
The typical approach for drying walls damaged by water is to install air movers (e.g., air fans) directing the air flow towards the affected areas. The air inside the room is sometimes conditioned with heating and/or dehumidification equipment to improve drying. Such configuration is not optimal in terms of energy consumption and drying time. Often, restoration is not successful, mold appears and building owners need to reconstruct.
There is a need for fast drying (typically under 48 hours for drywall structures) to avoid rebuilding, to reduce the impact on business interruption and to reduce the risk of cross-contamination. Furthermore, proper decontamination measures need to be addressed when required.
Different methods and systems have been proposed over the years to deal with these situations. One approach suggests the use of directional drying fans in order to direct the air flow where needed. For instance, U.S. Pat. No. 7,331,759, incorporated herein by reference, relates to an axial drying fan especially conceived for directing air flow to specific locations such as to corners at the intersection of wall/floor
Another tactic is to use heat exchangers in order to transfer part of the energy (heat) from the warm (and humid) air in the building before replacing it with the dry (and cold) air from the outside. For instance, U.S. Pat. No. 6,457,258, incorporated herein by reference, discloses a portable drying system mounted on a trailer. The system uses a counter-current heat exchanger to transfer part of the heat from the exhausting air to the entering air in order to increase temperature. The system further heats the entering air with a propane heater. U.S. Pat. No. 6,662,467, incorporated herein by reference, presents a similar system but adapted to elevated buildings. The air is heated to 125° F. (52° C.) and relative humidity is drawn to 5% using a propane heater. U.S. Pat. No. 2006/0189270, incorporated herein by reference, further proposed to combine the heat exchanger with a building positive pressurization and controlling the exiting flow of air to maintaining the desired positive pressure inside the building. In such a way, humid air from inside the building will flow through cracks and openings to the outside carrying humidity. Air from the outside is conditioned (dried and/or heated) before flowing to the inside. U.S. Pat. No. 2006/0185819, incorporated herein by reference, proposes a portable heat exchanger driven by a fan. Outside air is first cooled to remove humidity and then heated-up before entering the treated room. In all these cases, drying achieved by venting the affected rooms with large volumes of air being moved around and as a result, the building cannot be occupied during the drying procedure.
Injection systems have also been proposed with the purpose of substantially reducing the volume of air to be treated, which is more convenient when dealing with cavities such as walls and ceilings. For example, U.S. Pat. No. 8,468,716, incorporated herein by reference, discloses an injection drying system comprising a blower to which a plurality of flexible hoses are connected at one end and inserted into the wall at the other end. Pressurized air enters the wall cavity to speed up drying. U.S. Pat. No. 5,155,924, incorporated herein by reference, proposes an injection system specifically conceived for tongue-in-groove flooring. A set of diverters are provided for drying inside walls, floors and ceilings. The injection system combines the use of a dehumidifier and/or a heater as well as an exhaust conduit to reduce humidity before reinjecting air into the treated areas. U.S. Pat. No. 5,408,759, incorporated herein by reference, discloses a device comprising a flexible/expandable bag (air impermeable fabric or sheet material) with several air conduits adapted to be inserted into holes in the wall, forcing air from a blower device into walls cavities. Several bags can be inter-connected for large areas. U.S. Pat. No. 5,893,216, incorporated herein by reference, proposes an air distribution unit having several conduits of varying cross-section and length with nozzles attached in order to be inserted into the wall through perforated holes. The unit can inject air into the cavities and/or extract air form it. Small holes need to be drilled into the walls and repaired after drying. U.S. Pat. No. 6,647,639, incorporated herein by reference, discloses an improved forced air system for drying walls, which is driven by a blower in an open or closed loop configuration and operated in positive (injection) or negative (vacuum) pressure. The system uses injectors with an innovative locking tab mechanism and anti-clogging system. U.S. Pat. No. 6,886,271, incorporated herein by reference, extends the use of this system for floor drying by connecting the injectors to a floor plate. All these systems work on the air injection principle which require making holes on walls that need to be repaired after drying.
Alternatively, other methods preconize the use of existing holes in the wall in order to avoid perforating the walls. For instance, U.S. Pat. No. 5,761,827, incorporated herein by reference, discloses a process by which pressurized air is injected into hollow walls through existing holes around water supply piping for toilets, eliminating the need to drill new holes and repair them after drying. U.S. Pat. No. 5,555,643, incorporated herein by reference, describes an apparatus for injecting (or extracting) air to (or from) a wall cavity through electrical boxes, which provide access to (portions) of the wall cavities. U.S. Pat. No. 8,978,270, incorporated herein by reference, presents a method for drying a wall cavity also through light switches of power outlets. These systems are however limited to the wall cavity areas that can be reached from the existing holes locations.
Yet another injection approach consists on targeting interior layers of sheathing for the specific case when moisture locates on the outside side of sheathing, not easily accessible from the inside. U.S. Pat. No. 5,960,556, incorporated herein by reference, discloses a system for drying interior layers of sheathing in narrow wall spaces. It uses nozzles with circumferential orifices that, once they are inserted into the wall structure through proper holes perforated for this purpose, face the targeted wall spaces between layers.
Besides the drying methods, there have also been some efforts to develop control and monitoring software to assist the drying procedure. U.S. Pat. No. 9,015,960, incorporated herein by reference, discusses a drying apparatus comprising a heating system operated to rise temperature to the desired level, a conduit to exhaust humid air out of the room when required, and a set of sensors to control temperature and humidity within the treated room. The apparatus works continuously until the optimal humidity is reached. U.S. Pat. No. 7,403,126 discloses an apparatus, system and method to provide drying procedure information through a user interface. U.S. Pat. No. 8,006,407, incorporated herein by reference, presents a drying system that provides enhanced drying through the use of remote sensors and control devices. U.S. Pat. No. 2006/0185838, incorporated herein by reference, discloses a method to control humidity through the use of heat exchangers comprising heating elements that operate when needed to reduce the relative humidity of the air entering the dried space.
Furthermore, when a structure is affected by water damage, possible contamination by molds is an additional concern besides drying. Molds spores are present everywhere, inside and outside buildings, and normally do not constitute a problem for human health or materials integrity. However, when favorable conditions (nutrients, temperature and humidity) are met, mold spores that have settled inside a building, for instance inside wall cavities, can grow at a fast pace. Therefore, a goal of water damage restoration is to dry and also to decontaminate the affected structures when needed to avoid rebuilding, which also implies a loss in time, money and user comfort.
In this sense, U.S. Pat. No. 5,408,759 and U.S. Pat. No. 5,960,556, both cited before, also mentioned the possibility to inject deodorants, disinfectants, fungicidal or ‘other treatments’ into the wall cavities. U.S. Pat. No. 7,357,831, incorporated herein by reference, proposes a combined approach to control humidity and mold through a heat exchanger (similar to the ones described above) and to add HEPA filters and UV lights to kill mold spores flowing in the air stream. U.S. Pat. No. 6,327,812, incorporated herein by reference, proposes a method of killing organisms and removing substantially the remains from the treated enclosure. It is based on heating-up the building surfaces to temperatures between 120-300° F., supposedly killing several microorganisms (mold, insects, bacteria, etc.). The combined use of ozone is preferred to increase effectiveness. U.S. Pat. No. 6,892,491, incorporated herein by reference, further improves this system by creating a negative pressure within the treated space and by increasing the air temperature heating range to 110-400° F. U.S. Pat. No. 2005/0066537, incorporated herein by reference, discloses a system for wall cavity decontamination by injecting and/or extracting air or biocides. The method includes an evacuation phase (to remove existing contaminants) that can be performed in extraction, injection or close-loop modes, a decontamination phase that is performed by exposing the contaminants to microwave radiation and/or biocides, and a lock-down phase to trap the remaining (non-viable) contaminants into the cavity.
In view of this, there remains a need in the art for a system for wall restoration after water damage that is compact, easy to use, more efficient and safe, that provides the possibility to effectively dry structures (e.g., wall structures) and decontaminate them when required.
According to various aspects, the present technology relates to a gas injection device for drying and/or decontamination of a building structure, the gas injection device comprising an injector module, the injector module having an inner lumen defined by as external wall, the external wall defining a distal insertion portion for insertion of the injector module into the building structure and a proximal ventilation portion for providing air flow into the inner lumen of the injector module, the distal insertion portion and the proximal ventilation portion being in fluid communication with one another through the inner lumen, wherein the wall of the proximal ventilation portion comprises a plurality of ventilation openings configured to direct air flow into the inner lumen of the injector module.
According to various aspects, the present technology relates to a gas injection device for injection of gas into a cavity in a building structure, the gas injection device comprising: an injector module; a ventilation module; a casing module for assembling the ventilation module with the injector module; and a noise reduction module connected to the casing module.
According to various aspects, the present technology relates to a gas injection device for injection of gas into a building structure, the gas injection device comprising: an injector module; a ventilation module; a casing module for assembling the ventilation module with the injector module; and an injection duct connected to the casing module.
According to various aspects, the present technology relates to a gas extraction device for drying and/or decontamination of a building structure, the gas extraction device comprising an extractor module, the extractor module having an inner lumen defined by as external wall, the external wall defining a distal insertion portion for insertion of the extractor module into the building structure and a proximal ventilation portion for providing air flow into the inner lumen of the extractor module, the distal insertion portion and the proximal ventilation portion being in fluid communication with one another through the inner lumen, wherein the wall of the proximal ventilation portion comprises a plurality of ventilation openings configured to direct air flow into the inner lumen of the extractor module.
According to various aspects, the present technology relates to a gas extraction device for extraction of a gas from a building structure, the gas extraction device comprising: an extractor module; a ventilation module; a casing module for assembling the ventilation module with the extractor module; and a noise reduction module connected to the casing module.
According to various aspects, the present technology relates to a gas extraction device for extraction of gas from a building structure, the gas extraction device comprising: an extractor module; a ventilation module; a casing module for assembling the ventilation module with the extractor module; and an injection duct connected to the casing module.
According to various aspects, the present technology relates to a gas injection system for injection of a gas into a building structure, the gas injection system comprising: a distribution unit; one or more gas injection device as defined herein, in fluid communication with the distribution unit; and a drying module in fluid communication with the distribution unit.
According to various aspects, the present technology relates to a gas extraction system for extraction of a gas from a building structure, the gas extraction system comprising: one or more gas extraction device as defined herein; and a gas recirculation module in fluid communication with the one or more gas extraction device.
According to various aspects, the present technology relates to a gas circulation system for circulation of a gas into a building structure, the gas injection system comprising: a gas injection unit comprising a gas distribution unit in fluid communication with one or more gas injection device; a gas extraction unit comprising a gas recirculation module in fluid communication with one or more gas extraction device; and a gas generator in fluid communication with the gas injection unit and the gas extraction unit.
According to various aspects, the present technology relates to a gas injection device for injection of gas into a building structure, the gas injection device comprising: an injector module; a casing module for assembly with the injector module; and a noise reduction module connected to the casing module; wherein the injector module comprises a plurality of ventilation openings for allowing air into the injector module.
According to various aspects, the present technology relates to a gas injection device for injection of gas into a building structure, the gas injection device comprising: an injector module; a casing module for assembly with the injector module; and an injection duct connected to the casing module; wherein the injector module comprises a plurality of ventilation openings for allowing air into the injector module.
According to various aspects, the present technology relates to a gas extraction device for extraction of a gas from a building structure, the gas extraction device comprising: an extractor module; a casing module for assembly with the extractor module; and a noise reduction module connected to the casing module; wherein the extractor module comprises a plurality of ventilation openings for allowing air into the extractor module.
According to various aspects, the present technology relates to a gas extraction device for extraction of gas from a building structure, the gas extraction device comprising: an extractor module; a casing module for assembly with the extractor module; and an injection duct connected to the casing module; wherein the extractor module comprises a plurality of ventilation openings for allowing air into the extractor module.
Other aspects and features of the present technology will become apparent to those ordinarily skilled in the art upon review of the following description of specific embodiments in conjunction with the accompanying drawings.
Further features and advantages of the present disclosure will become apparent from the following detailed description, taken in combination with the appended drawings, in which:
It is to be expressly understood that the description and drawings are only for the purpose of illustrating certain embodiments of the present disclosure and are an aid for understanding. They are not intended to be a definition of the limits of the disclosure and/or of the technology.
The present technology is explained in greater detail below. This description is not intended to be a detailed catalog of all the different ways in which the technology may be implemented, or all the features that may be added to the instant technology. For example, features illustrated with respect to one embodiment may be incorporated into other embodiments, and features illustrated with respect to a particular embodiment may be deleted from that embodiment. In addition, numerous variations and additions to the various embodiments suggested herein will be apparent to those skilled in the art in light of the instant disclosure which do not depart from the instant technology. Hence, the following specification is intended to illustrate some particular embodiments of the technology, and not to exhaustively specify all permutations, combinations and variations thereof.
As used herein, the singular form “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise.
The term “about” is used herein explicitly or not, every quantity given herein is meant to refer to the actual given value, and it is also meant to refer to the approximation to such given value that would reasonably be inferred based on the ordinary skill in the art, including equivalents and approximations due to the experimental and/or measurement conditions for such given value.
The expression “and/or” where used herein is to be taken as specific disclosure of each of the two specified features or components with or without the other. For example “A and/or B” is to be taken as specific disclosure of each of (i) A, (ii) B and (iii) A and B, just as if each is set out individually herein.
In some embodiments, the present technology relates to an apparatus and control method that may be operated in different modes according to the task in hand: (a) quite mode; (b) optimized drying, and/or (c) decontamination. The approach is based on injection and/or extraction of a gas (conditioned or not) into a wall cavity through holes made for the purpose of drying and/or decontaminating materials inside cavities such as in walls, floors, ceilings, and such.
Injection/extraction is favored in order to reduce the volume of air being treated. When injecting gas into holes formed in a structure (e.g., wall) through injectors, the injectors may comprise holes themselves to promote drying of the external walls.
Most of the time, holes are cut in non-visible areas, such as behind electrical heaters, plinths and such. The holes made on the cavities are sealed after restoration following an existing procedure using dedicated wall pucks. The large dimensions of these holes (compared to systems using nozzles) are intended to increase gas flow inside the cavity.
In one embodiment, the present disclosure relates to a gas injection device for injection of gas into a wall. In some instances, the gas injection device of the present disclosure injects gas into a wall in order to dry a wall after water damages. In some instances, the gas being injected is air.
In one embodiment, the present disclosure relates to a gas extraction device for extracting a gas from a wall. In some instances, the gas extraction device of the present disclosure extracts gas from a wall in order to decontaminate a wall. In some instances, the gas being extracted is ozone, chlorine dioxide, or other.
In one embodiment, the present disclosure relates to a gas injection system using the gas injection device of the present disclosure for injecting gas into a wall.
In one embodiment, the present disclosure relates to a gas extraction system using the gas injection/extraction device of the present disclosure for extracting gas from a wall.
In one embodiment, the present disclosure relates to a gas circulating system using both the gas injection device as defined herein and the gas extraction device as defined herein to circulate gas within a wall. In some instances, the gas circulating system of the present disclosure is used to dry and to decontaminate a wall.
Although walls will be used herein to explain the present technology, it is to be appreciated that the devices and the systems of the present disclosure may also be used to dry and/or decontaminate floors and/or ceilings.
As used herein, the term “gas” refers to a state of matter wherein particles are widely separated from one another, and consequently have weaker intermolecular bonds than liquids or solids. A pure gas may be made up of individual atoms (e.g., a noble gas like neon), elemental molecules made from one type of atom (e.g., oxygen), or compound molecules made from a variety of atoms (e.g., carbon dioxide). A gas mixture would contain a variety of pure gases much like the air. As used herein, the term “air” refers to a colorless, odorless, tasteless, gaseous mixture, mainly nitrogen (approximately 78 percent) and oxygen (approximately 21 percent) with lesser amounts of argon, carbon dioxide, hydrogen, neon, helium, and other gases. In some embodiments, the gas is air. In some other instances, the gas comprises ozone (O3) or chlorine dioxide (ClO2). In some other instances, the gas comprises additional active agents such as hydroxyl radicals (.OH), antibiotics or antiseptic agents.
As used herein, the expression “fluid communication” refers to a flow of gas or a flow of liquid or a flow of a mixture of gas and liquid between two or more components of the device and systems as defined herein.
The gas injection/extraction device and system of the present disclosure may be portable and several units may be installed simultaneously for treatment of small or large surfaces on single or multiple rooms. The gas injection/extraction device and system of the present disclosure may be operated with minimal disturbance to room users, with reduced particle generation and limiting air movement to the inside of the wall cavity instead of moving the whole volume of air in the room as preconized by drying approaches known in the art.
In drying mode, the gas injection/extraction device and system of the present disclosure may improve drying by the use of a conditioning and distribution component combined with dehumidification and/or heating units. In decontamination mode, the gas injection/extraction device and system of the present disclosure may deliver decontamination gas inside wall cavities through a conditioning and distribution component. In some embodiments, the gas injection/extraction system of the present disclosure may include a series of sensors (sensing changes in, for example, temperature, relative humidity, material's humidity or the like) with remote monitoring and software.
In some embodiments, the gas injection/extraction device is modular, allowing to replace components thereof depending on the type of application and/or to replace used or broken parts. The gas injection/extraction device of the present disclosure may be installed on a typical wall composed of gypsum boards with mineral wool in the internal wall cavity for insolation. Alternatively, the gas injection/extraction device of the present disclosure may be installed with other structures such as solid walls.
In some embodiments, the gas injection/extraction device of the present disclosure may be used to inject pressurized air from the room to the wall cavity, floors, ceilings or other cavities in order to promote drying while reducing particle generation and noise in the room. The gas injection/extraction device may be positioned into walls, floors and/or ceilings through perforated holes. In some instances, a remote monitoring system may be used to control drying parameters during treatment.
In one embodiment, the gas injection/extraction device and system of the present disclosure produce a uniform gas flow among wall openings and adjust the gas flow independently as required.
In one embodiment, the gas injection/extraction device and system of the present disclosure integrate an air conditioning and distribution component through which conditioned air flow is provided to several ventilation modules for optimized drying.
In one embodiment, the gas injection/extraction device and system of the present disclosure integrate an air conditioning and distribution component through which a decontaminant gas such as, but not limited to, chlorine dioxide, ozone, a mix of air and vaporized hydrogen peroxide, a mix of air and hydroxyl radicals, or the like, flows through several ventilation modules for decontamination.
Additional chemicals and chemical compositions may be used to decontaminate and/or to remove contaminates trapped into wall cavities.
i) Gas Injection Module
In some embodiments, the gas injection device of the present disclosure is used to inject gas into a cavity of a wall, a floor and/or a ceiling.
In this embodiment, the injector module (110) is located at the distal end (1001) of the gas injection device (100). The injector module (110) has a distal end (1101), a proximal end (1102) and an injector wall (1103) joining the distal end (1101) to the proximal end (1102) to define an internal lumen (1104). The injector module (100) has a shape and size that is suitable for insertion into a hole created in a wall.
The casing module (120) has a distal end (1201), a proximal end (1202) and a casing wall (1203) joining the distal end (1201) to proximal end (1202) to define an internal lumen (1204). In this embodiment, the distal end (1201) of the casing module (120) is connected to the proximal end (1102) of the injector module (110). In some embodiments, the distal end (1201) of the casing module (120) is shaped so it is suitable to accept an air purification module (102). The air purification module (102) comprises an HEPA filter and/or a sanitizing tablet releasing odor control, antiseptic agents or biocides, such as chlorine, sodium hypochlorite, calcium hypochlorite, or the like.
In this embodiment, the ventilation module (125) is located into the inner lumen (1204) of the casing module (120). In some instances, the ventilation module (125) is a speed regulated fan. It will be appreciated that the ventilation module (125) has a shape and a size suitable for fitting into the internal lumen (1204).
The noise reduction module (130) has a distal end (1301), a proximal end (1302) and a noise reduction module wall (1303) joining the distal end (1301) to the proximal end (1302); the noise reduction module wall (1303) defining an internal lumen (1304). In this embodiment, the distal end (1301) of the noise reduction module (130) is connected to the proximal end (1202) of the casing module (120).
The capping module (140) has a distal end (1401), a proximal end (1402) and a capping wall (1403) joining the distal end (1401) to the proximal end (1402); the capping wall (1403) defining an internal lumen (1404). In some instances, the capping module is an air inlet cap. In this embodiment, the distal end (1401) of the capping module (140) is connected to the proximal end (1202) of the casing module (120).
As best seen in
The injection module (110) also comprises a plurality of attachment means (111a-x) located along the injector wall (1103) that allow inserting and fitting the injection module (110) into a wall cavity (10). In this embodiment, the attachment means (111a-x) are protrusions extending from the outside surface of the injector wall (1103). A plurality of flaps (112a-x) is distributed along the internal surface of the injector wall (1103) to promote air flow into the wall cavity (10). The plurality of flaps (112a-x) comprising a plurality of inlets (113a-x) to lead air flow into a preferential direction into the wall cavity (10). In this embodiment, the injector wall (1103) follows a diagonal from the proximal end (1102) to the distal end (1101) with a particular angle (e.g. 30°) as depicted in
Another embodiment of the injector module is depicted in
The injector module (116) also comprises a plurality of ventilation openings (116a-x) along the injector wall (1163) through which air flows in direction to the external part of the wall (10) to improve drying. The shape and number of ventilation openings (116a-x) varies according to the targeted application. In the embodiment depicted in
In yet another embodiment, the injector module is depicted in
In some embodiments, the injector module (118) comprises an adjustable directional flow deviator (800), as best seen in
In some instances, the directional mobile deviator (800) locks into the injector module (118) through clapping system at the proximal (8002) end of the injector wall (8003) allowing the deviator to rotate into the preferred position. The locking systems is semi-tightly fixed into the selected position in such a way that is not affected by gas circulation but is still possible to rotate by hand to another position if require.
In some embodiments, as seen in
In this embodiment, the internal lumen (1204) of the casing module (120) has a shape suitable to accept the ventilation module (125) so that the entirety of the ventilation module (125) fits into the lumen (1204) of the casing module (120). The ventilation module (125) may be placed into the internal lumen (1204) of the casing module (120) through the proximal end (1202) opening of the casing (120). In some instances, the inner lumen (1204) of the casing module (120) and/or the exterior surface of the ventilation module (125) may comprise attachments means to firmly attach the ventilation system (125) into the inner lumen (1204) of the casing module (120).
The ventilation system (125) may be adjusted to the desired speed by regulating the voltage furnished by a power supply (400). In some instances, the ventilation system (125) is a 40×40×28 mm fan (model: PF40281B1-000U-A99 from Sunon® (Kaohsiung, Taiwan)) having a motor of 6 W (12V, 510 mA).
In some embodiments, the gas injection device (100) comprises a noise reduction module (130) which is best illustrated in
The noise reduction module (130) comprises a plurality of lateral air inlets (132a-x) and a second axial channel inlet (133) to allow air flow into the noise reduction module (130) from the capping module (140). In the embodiment depicted in
The capping module (140) is illustrated in greater details in
In some embodiments, the injector module (110), the casing module (120), the noise reduction module (130) and the capping module (140) have a substantially cylindrical shape. It will be appreciated that the injector module (110), the casing module (120), the noise reduction module (130) and the capping module (140) may be of another shape without departing from the present technology.
In some embodiments, the injector module (110), the casing module (120), the noise reduction module (130) and the capping module (140) are made from the same material. Examples of materials from which the modules of the gas injection device (100) may be made include, but are not limited to, reinforced resins such as, but not limited to, polycarbonate (PC), polyvinylchloride (PVC), thermoplastic polyurethane (TPU) etc. or a combination of such. In some instances, the internal and/or external surfaces are covered by an antimicrobial coating such as Parylene™. In some other embodiments, each of the modules of the gas injection device (100) is made from a different material. The materials that may be used to make the components of the gas injection device (100) will be apparent to the person skilled in the art.
In some embodiments, the gas injection device of the present disclosure is composed of the injector module (116) as depicted in
ii) Gas Extraction Module
In some embodiments, the gas injection device of the present disclosure may be used to extract gas from a cavity of a wall, a floor and/or a ceiling. In such embodiments, the gas injection device may be referred to as a gas extraction device. In some instances, the gas extraction device comprises the same components as the gas injection device however, instead of injecting gas into a cavity of a wall (e.g., gas flowing from the noise reduction module, through the casing module/ventilation system and through the injection module and injected into the cavity of the wall), the gas extraction device extracts a gas from a cavity of a wall. In these embodiments, the gas is extracted from the cavity of the wall into the injector module which then becomes an extractor module, through the casing module and then through the noise reduction module.
In some instances, the ventilation module for extraction mode is installed on a reverse position with respect to the injection mode in order to extract air from the cavity of a wall and force it into the gas extraction system. In some other instances, the ventilation module comprises a mechanism allowing to invert the direction of the gas flow.
In some embodiments, the gas ejection device of the present disclosure is composed of the ejector module (116) as depicted in
iii) Assembly of Gas Injection/Extraction Modules
As best seen in
In some embodiments, the noise reduction module (130) has a shape and size that allows it to fit entirely into the inner lumen (1404) of a capping module (140).
Once assembled, the inner lumen (1104) of the injector module (110), the inner lumen (1204) of the casing module (120), the inner lumen (1304) of the noise reduction module (130) and the inner lumen (1404) of the capping module (140) are in registration and/or aligned so as to form a passageway allowing a gas (e.g., air) to flow from the noise reduction module (130), through the ventilation module (125), through the casing module (120) and through the injector module (110). In the instances where the gas injection device (100) is inserted into a wall, the gas (e.g., air) coming out of the injector module (110) is directed into the wall.
The capping module (140) may be used with the gas injection device (100) of the present disclosure when the gas injection device (100) is not connected to a gas injection system of the present disclosure as will be discussed below.
It will be appreciated that the ways of assembling the gas injection device of the present disclosure are also applicable to the assembly of the gas injection device when it is used as a gas extraction device. In such instances, the ventilation module (125) is inserted into the casing module (120) on an inverted direction with respect to the position used in injection mode, or the ventilation module (125) used is capable to invert the direction of the gas flow.
iv) Gas Injection/Extraction
In some embodiments, the gas injection device of the present disclosure may be part of a gas injection system.
An example of drying module (210) is illustrated in
The distribution system (220) comprises a combination of one or more components, such as for example, but not limited to: one or more continuous tube (222) through which gas flows without possibility of exiting the tube (e.g., without injection outlets), one or more elbow sections (224) having different angles allowing to circumvent possible obstacles or to follow changes in surface direction; one or more injection tubing sections (226) having one or more injection outlets (230a-x, best seen in
In some embodiments, the one or more components of the distribution system (220) such as the continuous tube (222), the elbow sections (224), the injection tubing section (226) and the stoppers (228) are made from flexible resin materials such as polyethylene that can be installed and modified in situ and can be detached to be disposed after intervention to avoid the risk of cross-contamination. In another embodiment, the components of the distribution system are made of polystyrene fabric or other air tight material. Elbow sections (224) can be custom made for particular angles or fabricated in situ using a belt-loop and strap system.
In this embodiment, the injection tubing section (226) has a plurality of injection outlets (230a-x) (in this instance the injection outlets are holes). The plurality of injection outlets (230a-x) are in connection with a plurality of gas injection devices (300a-x), wherein each outlet in the plurality of injection outlets (230a-x) is connected to one gas injection device in the plurality of gas injection devices (300a-x) as depicted in
As shown in
In another embodiment of the gas injection system (200), when optimized drying is to be privileged over noise reduction mode, the gas injection module (300) may be used without a ventilation module (325), gas flow being assured by the drying module (210) operating at high gas velocity. The gas injection system (200) and the gas injection module (300) for such embodiment are depicted in
The distal end (3601) comprises a duct-to-casing connector (370) as illustrated in greater details in
The proximal end (3602) comprises a duct-to-injection outlet connector (380). In one embodiment, the duct-to-injection outlet connector (380) connecting the injection duct (360) to the injection tubing section (226) through the injection outlets (230a-x) is exactly the same as the duct-to-casing connector (370) shown in
In one embodiment, the connection between the injection outlets (230a-x) and the gas injection devices (300a-x) is an air-tight connection while allowing fluid communication (i.e., gas flow) between the distribution unit (220) and the gas injection devices (300a-x). In another embodiment, the connectors (230a-x) comprise a twist-fit connector such as the one shown in
In some other embodiments, the gas injection device of the present disclosure may be used to extract gas from a wall (e.g., from the cavity of a wall). In such embodiments, the gas extractor may be used to, for example, decontaminate a wall (e.g., decontamination mode).
In some embodiments requiring silent operation of the gas injection system (200), the gas injection device (300) further comprises a noise reduction module (not shown) similar to the one previously described. In such a case, the geometry of the duct-to-casing connector (362) is adapted to receive the noise reduction module (330).
In some embodiments, the present disclosure provides a gas circulation system for circulating a gas into a cavity of a wall. An example of a gas circulation system (400) is illustrated in
Once the gas circulating in the system has acquired the desired properties, the remaining gas is directed to the gas destruction unit (450) via a duct (451) located at the proximal end of the gas generator (410) and evacuated to the ambient or confined room or other via the evacuating duct (452). The concentration of gas found inside the room defined by the walls being dried and/or decontaminated may be monitored and may be an indication on the speed and duration of the drying and/or decontamination process. On a preferred embodiment, the treated space is confined within a hermetical containment, which acts as barrier to gas leakage to adjacent areas.
The extraction unit (440) is illustrated in greater details in
In the embodiment, wherein the gas injection device of the present disclosure is used as a gas extraction device, the ventilation module is set to expel the gas incoming from the injector module out of the casing module and out of the injection duct, which in such embodiment, could be said to be an extraction duct.
The devices and systems of the present disclosure can be operated through a power supply. For most applications, an AC power can be employed. Alternatively, a wireless configuration may be used for overcrowded spaces or areas with difficult access. In such instances, alternative energy supplies (or a combination of them) may be preferred such as, but not limited to: rechargeable batteries, solar cells, or the like.
In some embodiments, the gas injection device and the systems of the present disclosure may be monitored and/or controlled via a wireless connection as illustrated in
In some instances, such as illustrated in
In another embodiment, the present disclosure relates to a monitoring system for monitoring the progress of the gas injection device and the gas injection system defined herein via a control software (700) for which a simplified flow diagram is illustrated in
It is understood that the data reported in the present specification are only given to illustrate the present disclosure and may not be regarded as constituting a limitation thereof.
While the present disclosure has been described in connection with specific embodiments thereof, it will be understood that it is capable of further modifications and this application is intended to cover any variations, uses, or adaptations of the present disclosure following, in general, the principles of the present disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the present disclosure pertains and as may be applied to the essential features hereinbefore set forth, and as follows in the scope of the appended claims.
All published documents mentioned in the present specification are herein incorporated by reference.
This application claims the benefit of and priority to U.S. provisional patent application No. 62/509,896, filed on May 23, 2017, the content of which is herein incorporated in this entirety by reference.
Number | Date | Country | |
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62509896 | May 2017 | US |