阅读说明：本技术 具有紫外灯处理的水系统地板接口 (Water system floor interface with ultraviolet lamp treatment ) 是由 C·格舍尔 R·B·布达希安斯 C·L·开普曼 于 2019-08-16 设计创作，主要内容包括：紫外(UV)灯消毒系统(10),用于在将水提供至用水设备之前处理水。一个或多个UV发光二极管(LED)被定位在水系统地板接口内,从而使流过系统的水暴露于杀菌灯处理。(An Ultraviolet (UV) lamp disinfection system (10) for treating water prior to providing the water to a water-using facility. One or more UV Light Emitting Diodes (LEDs) are positioned within a water system floor interface so that water flowing through the system is exposed to germicidal lamp treatment.)

1. A water system floor interface (10) for a vehicle, comprising:

a floor mounting assembly (18);

a UV interface assembly (20) including an interior space (30) in which a UV unit (34) is disposed, and a water line (32), the water line (32) including one or more turns and being made of a material transparent to UV, wherein the one or more turns of the water line are wound around the UV unit.

2. The system of claim 1, wherein one or more UV LEDs are positioned within the UV unit.

3. The system according to any of the preceding claims, wherein one or more UV OLEDs are positioned within the UV unit.

4. The system according to any one of the preceding claims, wherein the water line comprises a first end (50) for receiving water from the onboard water tank and a second end (52) for providing treated water to the water utility.

5. The system of any preceding claim, wherein the floor mounting assembly includes a chamber (26), the chamber (26) being sized and configured to receive the UV interface assembly (20).

6. The system of any preceding claim, wherein the floor mounting assembly (18) comprises an outer flange (22), the outer flange (22) being configured to abut a floor surface (14).

7. The system of claim 6, wherein the floor surface comprises a lavatory floor, a galley floor, or a floor panel.

8. The system of any preceding claim, wherein the UV interface assembly comprises an electrical interface (36).

9. The system of claim 8, wherein the electrical interface is positioned on an upper surface of the UV interface assembly.

10. The system of claim 8, wherein the electrical interface is positioned on a lower surface of the UV interface assembly.

11. The system of any preceding claim, wherein the UV interface assembly comprises a potable water interface (38), the potable water interface (38) configured to mate with a water distribution line that provides water to a water utility.

12. The system of any preceding claim, wherein the UV interface assembly includes a water shut-off feature (40).

13. The system of any preceding claim, further comprising a cover (42).

14. The system of any of the preceding claims, further comprising a set of arrows indicating when the UV interface assembly and the floor mounting assembly are properly aligned.

15. The system of any of the preceding claims, wherein the UV interface assembly is angularly adjustable within the floor mounting assembly to adjust to different on-board plumbing configurations.

Technical Field

Embodiments of the present disclosure generally relate to an Ultraviolet (UV) lamp disinfection system for treating water prior to providing the water to a water treatment facility. One or more UV Light Emitting Diodes (LEDs) are positioned at the water system floor interface so that water flowing through the system is exposed to germicidal lamp treatment.

Background

To ensure water quality, it is necessary to disinfect water aboard passenger vehicles. This may include disinfecting the potable water, which is stored in a self-contained potable water tank on the vehicle. The water held in the tank is ultimately used to provide a beverage maker, sink for washing hands, toilet for flushing, other water-using equipment, or otherwise disposed on the vehicle for different forms of water use or consumption, such as a humidifier, sprinkler system, and the like. As an example, an on-board water system is a complex system that typically includes a water tank with a conduit and a pressurized system for providing water to different locations of use.

Water quality, particularly potable water quality, on passenger vehicles and equipment, such as aircraft, trains, ships and vessels, and the like, is a concern for regulatory agencies. The regulatory standards that have been promulgated require that water onboard passenger vehicles meet certain standards, such as the US EPA aircraft drinking water regulations. Therefore, passenger airlines and other transportation companies must meet relevant drinking water standard(s). If not, the aircraft water system must accordingly be subjected to a disinfection process according to a specific protocol and tested again. This may result in the aircraft being prohibited from takeoff until the water quality is re-tested and it is determined that the water management system is free of microbial contamination.

Consequently, airlines and other passenger vehicle companies must ensure that potable water (i.e., potable water) carried on board an aircraft is suitable for human consumption by employing appropriate disinfection protocols and by preventing cross-contamination during filling of water. However, sterilization at filling and periodic sterilization sampling do not always adequately address contamination that may occur in the tank and/or when water is used on board the aircraft and leaves the tank. For example, air must be periodically introduced into the water storage and distribution system on board the aircraft to maintain pressurization and to drain the system during routine maintenance. This air may introduce airborne pathogens or bacteria that may multiply and cause unclean conditions and unacceptable water quality in the intervals between sampling or sterilization processes. Indeed, since water storage and dispensing systems are routinely exposed to the external environment, there is no always assurance that the quality of the potable water in the water holding tank will not be subjected to some form of additional treatment. In addition, the holding tank is often emptied at the end of a voyage, thereby preventing water freezing or other bacterial accumulation. This may also be a breeding ground for microorganisms or other biofilm, as the inner surface of the supply tank is then subjected to moist air (potentially) for several hours until the surface dries.

In particular, microorganisms and biofilm may contaminate water tanks stored on self-contained drinking water supplies, such as those located on passenger vehicles. Accumulation may occur along the interior surfaces of the tank and/or the water distribution lines. Bacteria, viruses, spores, molds, algae, or other microorganisms may also grow in the water holding tanks and/or distribution lines.

The present assignee has pending applications and issued patents relating to water treatment at the time of filling (U.S. patent No. 9,061,923), chemical water treatment (U.S. patent No. 7,666,317), water treatment in a tank (U.S. patent No. 10,266,426), water treatment along or in-line with a water distribution line (U.S. patent No. 9376333), and water treatment at the point of use (U.S. patent No. 9260323), (e.g., water treatment systems installed in toilets), and the like. These technical systems can be used to continuously treat and disinfect water stored in a water tank, as well as to treat water when filling or when providing water to a water use location. The present disclosure is distinguished from these previous water treatment systems because it is focused on providing space efficient devices, which are critical in aircraft space distribution for equipment. The disclosed water system floor interface is designed to be positioned in/under (considered a "dead space") the floor interface and function there. By not locating the water system architecture within a washroom and/or galley structure (valley monvent), the present disclosure provides a great value to the water system architecture.

Disclosure of Invention

Accordingly, embodiments described herein provide systems and methods for treating and disinfecting water contained in a drinking-water tank. These systems typically use one or more UV LEDs positioned within the floor interface and configured to emit UV light/radiation into the water through which the UV light/radiation flows.

There is therefore provided a water system floor interface for a vehicle, comprising: a floor mounting assembly; a UV interface assembly including an interior space in which the UV unit is disposed, and a water line including one or more turns and made of a material transparent to UV, wherein the one or more turns of the water line wrap around the UV unit. Within the UV unit one or more UV LEDs or UV OLEDs may be positioned. The water line may have a first end for receiving water from an on-board water tank and a second end for providing treated water to the water utility. The floor mounting assembly may define a chamber sized and configured to receive the UV interface assembly.

In some examples, the floor mounting assembly includes an outer flange configured to abut a floor surface. The floor surface may comprise a lavatory floor, a kitchen floor or a floor panel. The UV interface assembly may include an electrical interface, in some examples, the electrical interface is positioned on an upper surface of the UV interface assembly. In other examples, the electrical interface is positioned on a lower surface of the UV interface assembly. The UV interface assembly may also include a potable water interface configured to cooperate with a water distribution line that provides water to a water utility. The UV interface assembly may also include a shut off feature or cap.

A set of arrows may also be provided that indicate when the UV interface assembly and the floor mounting assembly are properly aligned. Additionally or alternatively, the UV interface assembly may be angularly adjusted within the floor mounting assembly to adjust to different on-board plumbing configurations.

Drawings

Fig. 1 shows a schematic diagram for possible locations of a water system floor interface on a vehicle, such as an aircraft.

Fig. 2A shows a perspective view of a water system floor interface.

Figure 2B illustrates a side plan view of the water system floor interface of figure 2A. Fig. 3 shows an exploded view of a water system floor interface showing a UV interface assembly and a floor mounting assembly.

Fig. 4 shows a perspective view of the UV interface assembly mounted within the mounting assembly.

Fig. 5 shows a top perspective view of the UV interface assembly.

Fig. 6 shows a top plan view of the UV interface assembly of fig. 5.

Fig. 7 shows a top perspective view of a UV interface assembly with a water shut-off feature.

Fig. 8 shows an exploded view of a water system floor interface showing how the UV interface assembly can be turned to different positions in the floor mounting assembly.

Detailed Description

Chlorination or other chemical treatments are not always effective in reducing or eliminating bacteria located under protective biofilms. On the other hand, Ultraviolet (UV) light treatment can destroy bacteria, viruses, spores and molds in water. Ultraviolet light can purify water by inactivating biological impurities. Ultraviolet light is typically designed to break links in the DNA of these microorganisms, rendering them inactive and non-renewable. The hydrogen bonds that link the DNA strands together, which are critical, break when exposed to light having a wavelength between about 220nm and about 310 nm. In a specific example, the range may be about 250nm to 270 nm. In a more specific example, there may be a single unique wavelength of 254 nm.

There are a variety of water treatment solutions that have been adopted and/or studied for use on board an aircraft. Providing Ultraviolet (UV) light to the water in the system has been found to be advantageous because the treatment does not change the taste or smell of the water, the treatment kills bacteria, viruses and protozoa, the system is compact and easy to use, and it prevents biofilm if the system is kept clean. One particular water treatment method that has been discovered is the use of ultraviolet light emitting diode (UV LED) light for water treatment. The use of UV LED light may use a wide UV band with multiple LED wavelengths and may provide higher power output with less power consumption than conventional UV lamps. UV LEDs have a longer lifetime, start quickly without the delay time of an embedded system to get the UV lamp source to its optimum UV energy output, and contain no mercury.

These UV LED sources are used at points of use and along water lines, such as in-line water treatment. However, since water is supplied from the water distribution line to the water consuming device (e.g., a sink faucet, a toilet, a coffee maker connection, or any other water consuming device that draws water from an on-board water tank), it is not believed that any type of UV light source has been mounted at the floor interface for water treatment. The present inventors have determined that it is desirable to provide a system that can be installed in the floor of an aircraft such that the lower surface is connected to a water distribution line and the upper surface is connected to a water supply line that directs water to a water utility.

As shown in fig. 1, the disclosed water system floor interface 10 is configured for use on a passenger vehicle 12. In particular, the water system floor interface is designed for use on a passenger aircraft, but it should be understood that embodiments provided by the present disclosure may be used on any type of vehicle, such as a water vehicle, camper, train or bus, or any other passenger vehicle having purified and/or treated water provided thereon to one or more water-using devices. Fig. 1 shows a water system floor interface 10 located within a floor surface 14 of an aircraft lavatory 16. The floor surface 14 may be a lavatory floor, a kitchen floor, or a floor panel.

Fig. 2A shows a side perspective view of the water system floor interface 10. Fig. 2B illustrates a side plan view showing the direction of water entering and exiting the water system floor interface 10. Fig. 3 shows a side plan exploded view of the water system floor interface 10. In these figures, a floor mounting assembly 18 is shown, which floor mounting assembly 18 may be used as a frame unit. A UV interface unit 20 is also shown. In these examples, the UV interface unit 20 is nested or otherwise mounted within the floor mounting assembly 18 to collectively form the floor interface 10. In particular, an outer flange 22 may be present on the floor mounting assembly 18. When the water system floor interface 10 is positioned within a floor, the outer flange 22 is substantially flush with the floor surface 14. (the outer flange may be slightly above or slightly below the floor surface, depending on the mounting hole size, seal size, and other factors.)

The floor mounting assembly 18 also features a water system plumbing connection 24 along the lower portion. The interface 24 mates with a water distribution line leading to and from a mains water supply such as a drinking water tank (not shown). The water system plumbing connection 24 may be angled to one side (as shown in fig. 2A and 2B), or it may be pointed straight down so that its central axis is perpendicular to the floor surface (as shown in fig. 3). The direction may depend on the configuration of the vehicle water distribution line.

Fig. 3 shows a UV interface assembly for mounting the assembly interface 54. The interface 54 allows the UV interface assembly 20 and the mounting assembly 18 to be aligned at the water inlet 56. This may define a self-sealing interface between the UV interface assembly 20 and the mounting assembly 18. Fig. 3 also shows that the mounting assembly 18 defines a chamber 26 into which the UV interface assembly 20 may be positioned during assembly or use. The chamber 26 of the mounting assembly 18 is defined by a sidewall 28. The side walls 28 are shown as being generally perpendicular to the outer flange 22, but it should be understood that the side walls may be tapered inwardly or outwardly to facilitate mating between the mounting assembly 18 and the UV interface assembly 20, if desired.

Fig. 2A, 2B and 4 show the UV interface assembly 20 mounted within the mounting assembly 18. Once the mounting assembly 18 is assembled relative to the floor surface 14 (which may be a lavatory floor, a galley floor, or a panel), the UV interface assembly 20 can be positioned in the mounting assembly chamber 26. This allows the system 10 to be assembled and serviced from above the floor or floor panel. By positioning the system at the floor surface 14, the space of the washroom or kitchen room is not used. This also makes it possible to make the connection directly at the location where the water distribution line is to enter the toilet or kitchen space. The water system floor interface 10 houses one or more UV LEDs for water disinfection.

Reference will now be made to features of the UV interface assembly 20, examples of which are illustrated by fig. 4-6. The UV interface assembly 20 defines an interior space 30 that supports a water line 32. In one example, the water line 32 has at least one turn (the number of turns may be defined as n + 1). The water line 32 may also present less than one full turn. The water line 32 may also have multiple turns, making it similar to a coiled tube. The number of turns of the water line 32 may be based on the amount of water to be treated, the available pressure to be applied to the water, or other factors. If multiple turns or loops are provided, they are provided to increase the treatment exposure of the water supply contained in the water line 32. The water line 32 may be a quartz, plastic or polymer tube or conduit that allows light having UV wavelengths to pass through. The water lines 32 may have a protective coating that allows the UV lamp to pass through but also prevents the accumulation of bacteria or other microorganisms. The water line 32 may be integrated into the outer flange and sealed to the cylindrical UV assembly at a portion of the mid-seat UV interface assembly 20.

The water line 32 may be provided with a first end 50 configured to mate with a first water line fitting and serve as an inlet to the water line. The water line 32 may also be provided with a second end 52 configured to mate with a second water line fitting and serve as an outlet to the water line 32.

As water enters the water line 32 and moves through the water line 32 (e.g., as water moves through one or more turns due to pressure), the water is subjected to a UV lamp treatment. The UV unit 34 is positioned in a middle region of the inner space 30. The UV unit 34 may support one or more UV LEDs. The UV unit 34 may support one or more UV OLEDs (organic light emitting diodes) that are more malleable and more easily shaped than conventional UV LEDs. Either option or any combination thereof may be used in accordance with the present disclosure.

The UV interface assembly 20 may also have an electrical interface 36. Fig. 2A, 2B and 3 illustrate an electrical interface 36 positioned on a surface of the assembly 20 and extending over a floor surface. (it should be understood, however, that electrical interface 36 may also be positioned below floor surface 14 if the aircraft architecture is adapted for such electrical connection-this is the case, for example, with the embodiment shown in FIG. 7, which does not show an electrical interface extending from the upper surface.)

The UV interface assembly 20 is also provided with a potable water interface 38. In all embodiments, the interface 38 extends generally above the floor surface 14. The potable water interface 38 is in fluid communication with the second end 52 of the water line 32. The potable water interface 38 is configured to mate with one or more water distribution lines leading directly to a water-consuming appliance.

As shown in fig. 7, the UV interface assembly 20 may be provided with a water shut-off feature 40. The water shut-off feature 40 may be used to prevent flooding above the floor surface 14 in the event of a water line break or other water leak.

The figure also shows a lid 42 that may be positioned over the chamber 30 containing the water line 32. The cover 42 is positioned to prevent damage to the system 10, as well as to protect passengers and crew from UV lamps emitted within the system.

Fig. 7 also shows an optional set of arrows that may be used to ensure proper installation of the UV interface assembly 20 and the floor mounting assembly 18 relative to each other. As shown, one of the arrows may be positioned on the UV interface assembly 20 and one of the arrows may be positioned on the floor mounting assembly 18. When the two components 18, 20 are properly aligned, the arrows will also align. If the assembly is not properly engaged or turned, the arrows do not align. This may provide a safety feature to ensure that the assemblies 18, 20 are mechanically correctly turned (clock) to achieve a robust UV lamp connection. If the arrows are not aligned, this indicates that the connection is not securely/properly assembled and the UV lamp will not activate or otherwise illuminate. If the connection is not secure, this safety measure will prevent light from escaping to protect any passengers or crew from exposure to the UV lamp.

Fig. 8 illustrates an alternative example of an embodiment that may ensure that the UV interface assembly and the floor mounting assembly of the system 10 are properly installed and turned relative to each other. This can help improve alignment with the underfloor duct. For example, as shown, if the interface 24 should be positioned at a different angle based on the angle of entry of the water line from the main tank, the UV interface assembly 20 may be adjusted from position "a" to position "B" within the framework shown. In other words, the UV interface assembly 20 may be assembled at a variety of angles relative to the frame of the floor mounting assembly 18. These various angles may also be modified to correspond to any type of above-floor piping arrangement. The UV interface assembly can be angled within the floor mounting assembly to adjust to different on-board plumbing configurations.

The primary features of the mounting assembly 18 and the UV interface assembly 20 may be made of a composite plastic or an injection molded plastic. Other materials are possible and are also considered to be within the scope of the present disclosure, including but not limited to steel, aluminum, titanium, polycarbonate, or any other suitable material suitable for aerospace engineering.

The UV LEDs or UV OLEDs described herein emit ultraviolet light having a wavelength that will destroy bacteria and thereby disinfect the water being treated. In one particular example, the emitted light may have a wavelength between about 220nm and about 310 nm. In a particular embodiment, the emitted light may have a wavelength between about 250nm-270 nm. In a more specific embodiment, the wavelength of the emitted light may be a single wavelength of 254nm only.

When UV energy is absorbed by the bacterial and viral reproductive systems, the genetic material (DNA/RNA) is recombined so that they can no longer multiply, killing the bacteria and eliminating the threat of disease. Thus, the UV treatment disinfects the water without added disinfecting chemicals.

The UV LEDs described herein are mounted or otherwise positioned such that they are capable of emitting light directly into the water line 32. Upon application, UV light is allowed and absorbed into the water stream. In one example shown in fig. 6, the water flow follows arrow 58 and the UV light energy follows arrow 60.

The disclosed water system floor interface 10 helps save valuable space on board a vehicle by providing water treatment at the floor surface level. In addition, maintenance and replacement of the UV interface assembly 20 is made easier because the UV interface assembly is accessible from above the floor and does not require removal of any underfloor plumbing assemblies.

The above disclosure provides examples of structures claimed by the appended claims. It should be understood that structures and methods described above and shown in the drawings can be changed, modified, added, or deleted without departing from the scope or spirit of the disclosure or the following claims.