WATER STERILIZATION CAP WITH REMOVABLE PARTICULATE FILTER AND/OR HYDRATION METER

A water sanitization cap for covering a bottle includes a barrel, a shell, and a waterproof compartment. The shell surrounds at least a portion of the barrel and includes an outer surface and an inner surface. The waterproof compartment is formed within the interior of the barrel. The waterproof compartment includes one wall formed at least in part from a transparent material, one or more light emitting diodes (“LEDS”), a sensor, and a filter cage. The LEDS are fixed within the waterproof compartment and oriented to shine light through the transparent material. The sensor includes an activation button. The sensor is configured to sense when the cap is in the installed position and supplies voltage to the activation button. The activation button is activated by a user in the installed position to supply voltage to the LEDS to emit light. The filter cage is operable to contain a filter.

FIELD OF TECHNOLOGY

This disclosure relates to water sterilization. Specifically, this disclosure relates to sterilizing water using a combination of ultra violet (“UV”) light and other filters.

BACKGROUND OF THE DISCLOSURE

Microorganism-free, pathogen-free, virus-free and bacteria-free water is a necessity for human life. Many times, in various different locations around the globe, clean, bacteria-free water is unavailable because of a variety of reasons.

Traditionally, this problem has been solved by single-use plastic water bottles. However, as a result, plastic waste from single-use plastic water bottles has grown exponentially. The plastic waste generated by disposed-of single-use plastic water bottles has generated a waste-management problem. Additionally, single-use plastic water bottles may be costly, especially in various locations around the globe.

Therefore, it is desirable to provide an apparatus for sterilizing and/or purifying water retrieved from bio-contaminated sources or sources of unknown contamination levels.

It is further desirable for the apparatus to operate together with typical reusable bottles.

It is yet further desirable for the apparatus to operate as a cap for typical reusable bottles.

Aspects of the disclosure include sanitizing water using both ultraviolet C (“UV-C”) rays and a particulate filter. The water may be contained within a conventional reusable bottle. A cap may cover the reusable water bottle.

The cap may include a UV-C module. The UV-C module may shine UV-C rays into the water within the water bottle. The UV-C module may destroy harmful bacteria and viruses within the water.

The cap may also include a filter cage. The filter cage may hold a filter. The filter may be a particulate filter. The particulate filter may filter the water from particulate matter, such as lead, chloride and fluoride. The filter may be disposable. The filter may be specific to a certain particulate matter. For example, one filter may effectively remove lead from the water, while another filter may effectively remove chloride from the water. Yet another filter may be a universal filter that removes a variety of particulate matter.

DETAILED DESCRIPTION OF THE DISCLOSURE

A water sanitization cap for covering a bottle is provided. The water sanitization cap may include a barrel. The water sanitization cap may also include a shell. The shell may surround at least a portion of the barrel. The shell may have an outer surface and an inner surface.

The cap may also include a waterproof compartment. The waterproof compartment may be formed within the interior of the barrel. The waterproof compartment may include at least one wall. The at least one wall may be formed at least in part from a transparent material. The transparent material may be quartz crystal.

Quartz crystal may be a material that enables UV-C rays to go through it. Any suitable material that allows passage of UV-C rays may be utilized to form a portion of a wall of the waterproof compartment. Such a material may include a flexible silicone material that enables the penetration of UV-C rays.

The cap may also include a light emitting diode (“LED”). The LED may be fixed within the waterproof compartment. The LED may be proximal to one end of the barrel. The LED may be oriented to shine light through the transparent material.

The light emitted from the LED may be ultraviolet light ranging between 100 and 400 nm. As such, the LED may be an ultraviolet C (“UV-C”) LED. A UV-C LED may produce UV-C light, also referred to herein as UV-C rays. UV-C light may be short-wave UV rays in the range of 100-280 nanometers. In some embodiments, the light emitted from the UV-C LED may preferably be about 278 nm.

UV-C rays may penetrate microbial cells included in liquids and/or translucent liquids. UV-C rays may destroy the active core (nucleic acids) of the microbial cells. The microbial cells may no longer be viable without the active core. After a period of time, the non-active microbial cells may revert to fundamental constituents, such as carbon dioxide (002), and trace elements, such as N (Nitrogen), P (Phosphorus), 0 (Oxygen) and S (Sulfur).

It should be appreciated that the UV-C rays may be produced, by the LED, without the use of toxic mercury. Toxic mercury may be harmful if ingested.

In some embodiments, the cap may include a safety feature to prevent damage from UV-C rays. The safety feature may guard an unprotected eye or skin which may be damaged by UV-C rays. The safety feature may restrict the UV-C LED from being activated unless the cap is secured onto a bottle. The safety feature may include one, two or more pins included in an inner surface of the shell. The one, two or more pins may restrict the UV-C LED from activating unless the pins are depressed. The pins may not be depressed when the cap is detached from a bottle. The pins may be depressed when the cap is screwed onto, or otherwise secured to a bottle.

The cap may also include a sensor. When activated, the sensor may apply a voltage to the LED to cause the LED to emit light.

In some embodiments, sensor may be a touch sensor. The touch sensor may respond to a single touch, double touch, multi-touch or any other suitable predetermined touch pattern. A single touch may initiate the display of the remaining battery charge.

A double touch may initiate activation of the UV-C LED for a first predetermined period of time. The first predetermined period of time may be 30 seconds, 60 seconds, 90 seconds or any other suitable period of time. Exposure of the contents of the bottle to the UV-C LED rays for the first predetermined period of time may be suitable for destroying microbial cells found in liquids from mildly to moderately contaminated sources. Such mildly to moderately contaminated sources may include unfiltered tap water and water from fountains. Exposure of a UV-C LED to a six to one hundred and twenty eight ounce bottle for the first predetermined time period may sterilize the contents of the bottle to 99.99%.

A multi-touch, such as a three, four, five, six or other suitable amount of touches, may initiate activation of the UV-C LED for a second predetermined period of time. The second predetermined time period may be 90 seconds, 120 second, 150 seconds, 240 seconds, 360 seconds or any other suitable time period. Exposure of the contents of the bottle to the UV-C LED rays for the second predetermined period of time may be suitable for destroying microbial cells found in liquids from moderately to highly contaminated sources. Such moderately to highly contaminated sources may include water from lakes and ponds. Exposure of a UV-C LED to a 6-128-ounce bottle for the second predetermined time period may sterilize the contents of the bottle to 99.9999%.

The cap may also include a filter cage. The filter cage may be operable to contain a filter. It should be appreciated that the filter cage and/or the filter may be replaceable. The filter cage may include a filter cage threaded section.

The water sanitization cap may include a charging site. The charging site may be integral to the shell.

The cap may include a charging site. The charging site may be integral to the shell. As such, a portion of the shell may form the charging site. The charging site may charge a battery located within the cap.

It should be appreciated that the charging site may, in some embodiments, not include a charging port, or at least a readily discernable charging port. Examples of a readily discernable charging port may include a universal serial bus (“USB”) port or micro-USB port. For the purposes of this application, port-less may be understood to mean no readily discernable location for the uptake of charging power.

It should be further appreciated that even though the charging site may be port-less, the charging site may utilize a wired connection. In these embodiments, the shell itself may include at least two areas that may conduct electricity. The two areas may be constructed of metal. The first area may be a positive area. The positive area may act a positive charging pole. The second area may be a negative, or ground, area. The negative area may act as a negative charging pole. The positive area and the negative area may be in any suitable shape. An example of a shape may be a ring shape or concentric circle shape. An insulation area may insulate the positive area from the negative area. The insulation area may also be any suitable shape. An example of a suitable shape may be a ring shape. The insulation area may be constructed from an insulating material, such as plastic.

A charger may be used to charge the cap. The charger may be constructed to fit over the shell of the cap. The charger may include a charging terminal. The charging terminal may be built into the inner shell of the charger. The charging terminal may include positive and negative pins. The positive pin may be operable to contact the positive area on the cap. The negative pin may be operable to contact the negative area on the cap. When the charger is fit over the shell, the positive and negative pins may come in contact with the conductive material of the shell of the cap. Once in contact with the positive and negative areas on the cap, the positive and negative pins may charge the battery within the cap. It should be appreciated that the charger may be connected, using a wired connection, or a wireless connection, to a device that provides power. Such a device may include a laptop, electric outlet or any other suitable device.

There may be multiple embodiments for screwing the filter cage into the cap. A first embodiment may include a filter cage threaded section on the filter cage. The filter cage threaded section may be located on the upper outer surface of the filter cage. The filter cage threaded section on the outer upper surface of the filter cage may screw into a shell threaded section on the inner surface of the shell. As such, the filter cage threaded section and the shell threaded section may be complimentary to one another.

A second embodiment may include a filter cage threaded section on the filter cage. The filter cage threaded section may be located on the upper inner surface of the filter cage. The filter cage threaded section on the upper inner surface of the filter cage may screw into a barrel threaded section on an upper outer surface of the barrel. The upper outer surface of barrel may be the surface on the external portion of the barrel on the side that furthest from the UV-C LED. As such, the filter cage threaded section and the barrel threaded section may be complimentary to one another.

In some embodiments, the barrel may be, in whole, or in part, constructed from plastic. When the UV-C rays are emitted from the LED, micro-cracks may form in the portion of the barrel that is exposed to the light. Therefore, a shield, which may be constructed from a metallic material, such as stainless-steel, may protect the portion of the barrel from being exposed to the UV-C rays. In this way, the barrel is not exposed to, and possibly damaged by, the UV-C rays.

As such, the cap may include a shield. The shield may be stainless-steel. The shield may be constructed from any suitable metallic material. The shield may be constructed from any other suitable material. The shield may be operable to shield the barrel from light generated by the LED.

Additionally, at least a portion of the construction of the cap may be a pressure-fit construction i.e., the components within the cap may be pressure-fit to one another. For example, the shield may be pressure-fit to the barrel and the barrel may be pressure-fit to the shell. The pressure-fitting may be important because the construction may preferably not include glue. Glue may be undesirable because glue may degrade, and, as the glue degrades, it may leach into the water included in the bottle.

A foldaway straw may be constructed as part of the shell. The foldaway straw may be maintained in either an upright state or in a horizontal state. When the foldaway straw is in the horizontal state, the foldaway straw may partially or completely form a plane that is perpendicular to a longitudinal axis of the bottle.

A flow pipe may connect the foldaway straw, in an upright state, to an annular space between the filter cage and the barrel. The flow pipe may directly enable water to pass from the flow pipe into the foldaway straw. The flow pipe may indirectly enable water to pass from the flow pipe into the foldaway straw.

The shell may also include a detent. The detent may store the foldaway straw when the foldaway straw is in the horizontal state. The detent may include a hollow cavity. The sensor may fit into the hollow cavity. The sensor may be accessible when the foldaway straw is in the upright state.

The cap may include one or more other sensors. The one or more other sensors may be operable to measure water depth and/or water temperature. The one or more other sensors may be ultrasonic. The one or more sensors may be built-in probes, such as temperature probes. In some embodiments, the one or more other sensors may constantly remain active. In certain embodiments, the one or more other sensors may determine water data after a predetermined period of time has lapsed. The predetermined period of time may be thirty seconds, one minute, five minutes, thirty minutes or any other suitable time period. In other embodiments, the sensor may determine water data each time the cap is replaced on the bottle. The one or more sensors may be also be known as a hydration meter, as it measures the user's hydration.

Smart logic programming along with sensor calibration may enable the detection of false readings to avoid anomalies. For example, the sensor may determine when the cap is not placed on the bottle. Also, the sensor may determine when the level of the contents is not static, such as during transportation.

The cap may also include a transceiver. The transceiver may transmit and/or receive data from an associated device. The device may be a smartphone, computer, tablet or other suitable device. The transceiver may connect to the device using Bluetooth®, Wi-Fi, or any other suitable communication protocol. The transceiver may transmit water depth, water temperature and/or water sterilization status data to the device. The device may use the received water depth, water temperature and/or water sterilization status data to determine a user's total water consumption.

The device may include an application. The application may receive the water depth, water temperature and/or water sterilization status data. The application may combine the received water depth, water temperature and/or water sterilization status data with timestamp and/or geotagging data determined by the application. The combined data may enable the application to determine water consumption over a period of time, a specific time period and/or a day. The combined data, specifically the geotagging data may help calculate the water consumption when traveling or water consumption at a specific location. The application, based on the data, may instruct a user regarding hydration. Such instruction may include instructing a user to drink more water during specific times during the day and/or at specific locations. Such instruction may display to a user to the difference between water consumption at various geographic locations. For example, such instruction may display to a user the difference between water consumption at home and water consumption at an office location.

In some embodiments, the water sanitization cap may be used to sanitize surfaces, such as a keyboard, mouse, tablet, etc. In such embodiments, the cap may be waved within a predetermined proximity of the surface, e.g., one inch, two inches, three inches of four inches. The waving may be executed for a predetermined amount of time such as one minute or two minutes.

Apparatus described herein are illustrative. Apparatus in accordance with this disclosure will now be described in connection with the figures, which form a part hereof. The figures show illustrative features of apparatus in accordance with the principles of this disclosure. It is to be understood that other embodiments may be utilized and that structural, functional and procedural modifications may be made without departing from the scope and spirit of the present disclosure.

Apparatus may omit features shown or described in connection with illustrative apparatus. Embodiments may include features that are neither shown nor described in connection with the illustrative apparatus. Features of illustrative apparatus may be combined. For example, an illustrative embodiment may include features shown in connection with another illustrative embodiment.

FIG. 1shows a front view of a conventional water bottle102for use with embodiments of the invention.

FIG. 2shows a top-down perspective view of an exemplary sterilization cap200with a removable filter cage (shown partially at208) according to certain embodiments.

Removable filter cage208may hold a particulate filter (shown inFIG. 7). Sterilization cap200may sterilize water, or any other suitable liquid using both a particulate filter, which filters particles from the water, and a UV-C LED, which destroys microbial cells within the water.

Detent204may include a sensor (shown partially at212). Sensor212may be accessible when foldaway straw202in is a deployed stated. Sensor212may be a touch sensor. As such, sensor212may be sensitive to touch. In response to receipt of a single-touch, double-touch, multi-touch or any other suitable predetermined series of touches, sensor212may activate a UV-C LED (not shown) and/or light emitting diode206.

Cap200may include LED206. LED206may illuminate in order to indicate a status of cap200. LED206may illuminate various colors. Each of the colors may indicate a different operational status of cap200. In addition to the color of the illumination, the frequency of the illumination—e.g., whether the illumination is constant, quick-blinking, slow-blinking, etc.—may indicate various operational statuses of cap200. Exemplary operational statuses include low, medium and high sterilization status. In addition, a predetermined pattern and/or color of illumination may provide an indication of remaining battery charge.

Cap200may include shell210and a barrel (not shown). Shell210may encapsulate all or a portion of the barrel. The barrel may be obscured from view inFIG. 2because filter cage208may surround the barrel.

Cap200may be constructed from metallic materials, glass materials, quartz crystal materials, silicon materials, plastic materials, any other suitable materials or a combination thereof. Most preferably, shell210may be constructed at least partially from stainless steel, and the barrel may be constructed at least partially from plastic.

FIG. 3shows an illustrative top-down perspective view of an illustrative sterilization cap. InFIG. 3, foldaway straw202is shown in an undeployed state. As such, foldaway straw202is folded into the cavity formed by detent204.

FIG. 4shows an illustrative top-down view of an illustrative sterilization cap. InFIG. 4, foldaway straw202is shown in a deployed state. As such, sensor212is shown within detent204.

FIG. 5shows an illustrative top-down view of an illustrative sterilization cap. InFIG. 5, foldaway straw is shown in an undeployed state. As such, sensor212is not visible inFIG. 5.

FIG. 6shows an illustrative bottom-up view of an illustrative sterilization cap. Removable filter cage208is screwed into position around barrel608.

Removable filter cage208may be a modular, replaceable filter cage. The modular, replaceable filter cage may hold different filters. Water retrieved from various sources may include different particulates. As such, different filters may be utilized to filter different types of particles, such as lead, chlorine, neuro toxins and/or any other particles. Because the filter cage is preferably both modular and replaceable, one cap may be used to filter water from multiple sources.

There may be multiple embodiments for screwing removable filter cage208to the illustrative sterilization cap. A first embodiment may include threads on the outer portion of removable filter cage208. These threads on the outer portion of removable filter cage208may screw into threads on the inner portion of shell210.

A second embodiment may include threads on the inner portion of removable filter cage208. These threads on the inner portion of removable filter cage208may screw into threads on the outer portion of the barrel.

UV-C LED604may be operable to shine UV-C LED rays when activated. UV-C LED604may be included in an inner, waterproof compartment of barrel608.

FIG. 7shows an exploded view of an illustrative sterilization cap. The exploded view may show the threads on filter cage208in accordance with the first embodiment, as described above.

It should be appreciated that at least a portion of the construction of the cap may be a pressure-fit construction—i.e., the components within the cap may be pressure-fit to one another. For example, the shield may be pressure-fit to the barrel and the barrel may be pressure-fit to the shell. The pressure-fitting may be important because the construction may preferably not include glue. Glue may be undesirable because glue may degrade, and as the glue degrades, it may leach into the water included in the bottle.

Filter cage208may include outer threads702. Outer threads702may be operable to screw into threads (not shown) on the inner portion of shell210.

In some embodiments, filter cage208may be hollow. Filter cage208may house particulate filter704. In such embodiments, particulate filter704may perform the filtration. Particulate filter704may be replaceable.

Outer threads702may enable filter cage208to be removed. When filter cage208is unscrewed, particulate filter704may be removed and replaced with a particulate filter module.

In some embodiments, filter cage208and particulate filter704may be replaceable. As such, both filter cage208and particulate filter704may be disposable.

In certain embodiments, filter cage208and particulate filter704may be coupled to one another. As such, both filter cage208and particulate filter704may be replaceable and disposable together.

The illustrative sterilization cap may include a charging site. The charging site may be integrated into shell210. The charging site may include charging pins708and710. Charging pin708may be a positive or negative charging pin. Charging pin708may preferably be a positive charging pin. Charging pin708may form a positive connection with a printed circuit board (“PCB”)728. PCB728may be a printed circuit board that mechanically supports and electrically connects electrical or electronic components using conductive tracks, pads and other features etched from one or more sheet layers of copper laminated onto and/or between sheet layers of a nonconductive substrate. Other suitable conducting material may be used.

Charging pin710may be a positive or negative charging pin. Charging pin710may preferably be a negative charging pin. Charging pin710may form a ground connection with PCB728. Charging pin710may also contact the outer portion of shell210. Charging pin710may provide negative contact to the outer portion of shell210.

Spring712may be mounted to PCB728. Spring712may provide the flexibility to sensor212.

Charging ring714may be a positive or negative charging area. Charging ring714may preferably be a positive charging area. Charging ring714may be constructed from metallic material. Charging ring714may contact charging pin708.

LED206may be supported by support726.

Springs720and722may enable foldaway straw to be maintained in a deployed position or an undeployed position. Foldaway straw202may be supported by straw support724. When foldaway straw202is in an undeployed state, straw support724may provide a seal to the flow pipe that enables the water to flow from the bottle into foldaway straw202.

FIGS. 8A and 8Bshow illustrative cross-sectional views of an illustrative sterilization cap. The cross-sectional views may show the threads on filter cage208in accordance with the first embodiment, as described above.FIG. 8Ashows illustrative components of the sterilization cap.FIG. 8Bincludes arrows. The arrows show an illustrative path of water travel through the sterilization cap.

During water consumption through the illustrative sterilization cap, water inside the bottle travels through the bottom and peripheral openings of filter cage208and into inner portion of particulate filter704. The water then travels from particulate filter704through the internal openings of filter cage208and into the annular space between filter cage208and barrel608. As the water travels through inner portion of particulate filter704, impurities or contaminants get trapped inside particulate filter704, leaving the pure water accumulation in the annular space between filter cage208and barrel608.

The pure water travels out through the annular space between filter cage208and barrel608into flow pipe802. When foldaway straw202is in a deployed state, the water travels from flow pipe802into foldaway straw202.

Upon activation, and prior to water consumption, UV-C LED604may be activated. When activated UV-C LED604may be used to shine UV-C rays into a conventional reusable water bottle. The UV-C rays may be used to sterilize the contents of the conventional reusable water bottle.

The lower end of barrel608may be near UV-C LED604. Barrel608may be primarily constructed from plastic mated al. It should be appreciated that rays from UV-C LED604may create micro-cracks in the lower end of barrel608. As such, shield814, which may be constructed from a suitable metallic, such as stainless steel, or other suitable material. Shield814may protect lower portion of barrel608from exposure to the rays from UV-C LED604.

The inner compartment of barrel608may include various components such as UV-C LED604, battery804, PCB-A board806, 0-ring810, quartz crystal812, shield814and/or other suitable components. Battery804may connect, using wires (not shown) to PCB-A board806. UV-C LED604may be mounted on PCB-A board806. 0-ring810may surround quartz crystal812. 0-ring810may be constructed from silicon material. 0-ring810may enable the pressure-fit of the illustrative sterilization cap. 0-ring810may also prevent water from leaking into internal components of the illustrative sterilization cap.

Quartz crystal may be a material that enables UV-C rays to go through it. Any suitable material that allows passage of UV-C rays may be utilized to form a portion of a wall of the waterproof compartment inside the barrel. Such a material may include flexible silicone material that enables the penetration of UV-C rays. As such, quartz crystal812may be transparent. Also, quartz crystal812may maintain the waterproof properties of the inner compartment of barrel608. Quartz crystal812may enable the UV-C LED rays to shine out from the inner compartment of barrel608into a bottle (not shown).

In between filter cage208and shell210may be a gap, as shown at808. Gap808may enable a bottle to screw into the illustrative sterilization cap.

FIG. 9shows a bottom-up view of an illustrative sterilization cap. The bottom-up view may show threads on filter cage208in accordance with the first embodiment, as described above. It should be appreciated that filter cage208is not shown inFIG. 9.

The bottom view of the illustrative sterilization cap may show threads602on the inner portion of shell210. Threads602may screw into filter cage208(not shown). The bottom view of the illustrative sterilization cap may also show UV-C LED604and shield814.

The bottom view of the illustrative sterilization cap may also show bottom opening904. Bottom opening904may be the bottom opening of flow pipe802(not shown).

FIG. 10shows a bottom-up perspective view of an illustrative sterilization cap. The bottom-up perspective view may show threads on filter cage208in accordance with the first embodiment, as described above. It should be appreciated that filter cage208is not shown inFIG. 10. Threads602may screw into filter cage208(not shown).

FIG. 11shows a bottom-up view of filter cage208.

FIG. 12shows a top-down perspective view of filter cage208. The top-down perspective view may show threads on filter cage208in accordance with the first embodiment, as described above. Filter cage208may hold particulate filter704(not shown). Threads702are shown on the outer portion of filter cage208.

FIG. 13shows a cross-sectional view of filter cage208. The cross-sectional view may show threads on filter cage208in accordance with the first embodiment, as described above. Particulate filter704(not shown) may fit into filter cage208. Threads702are shown on the outer portion of filter cage208.

FIG. 14shows an exploded view of an illustrative sanitization cap. The exploded view may show the threads on filter cage208in accordance with the second embodiment, as described above.

In the second embodiment, barrel608may include outer threads, as shown at1402. Filter cage208may include inner threads1406. Inner threads1406may screw into outer threads1402.

At least a portion of the construction of the cap may be screw-fit construction—i.e., the components within the cap may screw into another component within the cap. For example, the filter cage may screw into the barrel.

At least a portion of the construction of the cap may be a pressure-fit construction—i.e., the components within the cap may be pressure-fit to one another. For example, the shield may be pressure-fit to the barrel and the barrel may be pressure-fit to the shell. The pressure-fitting may be important because the construction may preferably not include glue. Glue may be undesirable because glue may degrade, and as the glue degrades, it may leach into the water included in the bottle.

Circular cavity1404may be a cavity within detest204. The touch sensor (not shown) may fit into circular cavity1404. Circular cavity1404may be accessible when foldaway straw202is in a deployed state. As such, when foldaway straw202is in an undeployed state, access is blocked to touch sensor (not shown) within circular cavity104.

FIG. 15shows a cross-sectional view of an illustrative sanitization cap. The cross-sectional view may show the threads on filter cage208in accordance with the second embodiment, as described above.

The top of a water bottle (not shown) may have threads. The threads may screw into an illustrative sterilization cap. The threads of the water bottle may screw into threads1502. Threads1502may be located on the inside of shell210. Gap808may enable a bottle to screw into the illustrative sterilization cap.

A gasket (not shown) may be located on the ceiling of threads1502. The gasket may preferably be circularly shaped. The circular gasket may surround the ceiling of threads1502. The gasket may be constructed from silicon or any other suitable material. The gasket may seal a bottle to which the illustrative sterilization cap is secured. The gasket may provide a 360-degree seal, or complete seal of the contents of the bottle.

FIG. 16shows a bottom-up view of an illustrative cap. The bottom-up view may show the threads on filter cage208in accordance with the second embodiment, as described above. InFIG. 16, filter cage208is not shown.

FIG. 17shows a bottom-up perspective view of an illustrative cap. The bottom-up perspective view may show the threads on filter cage208in accordance with the second embodiment, as described above. InFIG. 17, filter cage208is not shown.

FIG. 18shows a bottom-up view of an illustrative filter cage. The bottom-up view of the illustrative filter cage may show the threads on filter cage208in accordance with the second embodiment, as described above.

FIG. 19shows a top-down perspective view of an illustrative filter cage. The top-down perspective view of the illustrative filter cage may show the threads on filter cage208in accordance with the second embodiment, as described above.

FIG. 20shows a cross-sectional view of an illustrative filter cage. The cross-sectional view of the illustrative filter cage may show threads on filter cage208in accordance with the second embodiment, as described above.

Thus, a sterilization cap with removable particulate filter and/or hydration meter, is provided. Persons skilled in the art will appreciate that the present invention can be practiced by other than the described embodiments, which are presented for purposes of illustration rather than of limitation. The present invention is limited only by the claims that follow.

FIG. 21shows a front view of a sanitization assembly1000comprising a sanitization cap1010including a handle1008having a strap1006and pair of pins1004removably fastened to a bottle (1020). Sanitization cap1010is similar in structure and function to sanitization cap (200) except as otherwise described below. The cap1010may include a fixed, removeable, or moveable handle1008. The handle1008may be affixed or rotatably coupled to a top surface, a side surface, or a surface most proximal to bottle1020. The handle1080may be removeable or fixed to the cap after being assembled at a manufacturing facility.

Cap1010further includes a sensor1030positioned within cap1010and configured to determine whether the cap1010is in an installed position or an uninstalled position. More specifically the sensor1030is positioned in the shell1012or barrel (not shown) of the cap1010but may be positioned in any position that the sensor1030may be capable of determining that the cap1010is in an installed position as shown inFIG. 21. Cap further includes a bottle facing surface1014positioned most proximate to a cap facing surface1022of the bottle1020in the installed position. Cap further includes a power supply and a wiring circuit. The power supply is in electrical communication with the sensor via the wiring circuit, and the sensor is in electrical communication with the UV-C LEDS604(SeeFIGS. 6 and 25-26). Sensor1030includes a circuit breaker (not shown) and an activation button1032. More specifically the circuit breaker is in electrical communication with the power supply via the wiring circuit and the circuit breaker is in electrical communication with the activation button1032. The activation button1032is in electrical communication with the UV-C LEDS604via the wiring circuit. In the installed position, the sensor allows the circuit breaker to supply power to the activation button1032. A user may then depress activation button1032with a thumb or finger or otherwise actuate activation button1032to supply voltage to the one or more UV-C LEDS604to illuminate the UV-C LEDS604. In the uninstalled position, the circuit breaker disallows electrical communication between the power supply and the activation button1032. When in the uninstalled position, activating the activation button1032does not supply power to the UV-C LEDS604. In some versions, the activation button1032is a component separate and apart from the sensor.

The sensor1030may include a contact sensor or a noncontact sensor. The contact sensor contacts a portion of the bottle1020in the installed position to supply voltage to activation button1032via, the circuit breaker. The noncontact sensor uses capacitive change, impedance change, or resistive change to activate or deactivate the supply voltage to the activation button1032via the circuit breaker. The resistance sensor is located proximate to the bottle facing surface1014of the cap1010and the resistance sensor1030engages the cap facing surface1022or a portion of the threads (not shown) of the bottle1020and determines an installed resistance in an installed position is less than an uninstalled resistance in an uninstalled position. For example, in the uninstalled position the uninstalled resistance may be an extremely high value such as an infinite resistance and in the installed position the value will be some value much less than the infinite resistance based on the material properties of the bottle1020. When a lesser resistance is detected by the sensor1030, sensor1030is configured to allow circuit breaker to supply power to the activation button1032.

In versions including proximity sensors, the bottle facing surface1014of the cap1010may not need to touch the cap facing surface1022of the bottle1020to indicate that the cap1010is in the installed position. The proximity sensor may include an impedance sensor, Hall effect sensor, an aluminum-detecting sensor, all metal sensors, a pulse-response sensors and/or other proximity sensors known in the art that determine a first body is proximate to a second body without the first body contacting the second body.

The impedance sensor is capable of detecting magnetic field loss due to eddy currents generated on a conductive surface of a metallic object by an external magnetic field. An external magnetic field is generated in the form of an alternating current by a coil (not shown) within the impedance sensor and a metallic portion (1026) of the bottle (1020) acts as a conductive surface that changes the impedance due to the metallic portion (1026) of the bottle (1020). The metallic portion (1026) of the bottle (1020) may include a metallic housing or a metallic ring (not shown) positioned proximal to the cap facing surface (1022). Predetermined values of impedance for the installed position and the uninstalled position are stored within a memory of the impedance sensor. The impedance sensor determines measured values of impedance and compares the measured values with the predetermined values of impedance. In the installed position the impedance sensor activates the supply voltage to the activation button1032and in the uninstalled position deactivates the supply, voltage to the activation button1032. Aluminum-detecting sensors and all-metal sensors operate similarly to the impedance sensor by comparing a predetermined value of the installed position and the uninstalled position with the measured impedance value when the cap in the installed and uninstalled positions and activating or deactivating the supply of voltage to the activation button1032.

The Hall effect sensor detects a sensed element such as a magnet1024or a magnetic portion of the bottle1020. The magnetic portion of the bottle1020having magnetic properties may include the housing or a metallic ring (not shown) having magnetic properties. When the Flail effect sensor becomes proximate to the magnet1024or magnetic property portion, the Hall effect sensor converts magnetically encoded information into an electrical signal when in the installed position and uninstalled position to respectively activate and deactivate the supply voltage to the activation button1032. The Hall effect sensor is capable of activating or deactivating the supply voltage when positioned 10 millimeters or less from the magnetic portion of the bottle or the magnet,

FIG. 22shows an illustrative top-down perspective view of illustrative sanitization cap1100. Cap1100is similar to cap200described above except as otherwise noted below. Cap1100is configured to be removably coupled to bottle1020. Cap1100is fitted with a pivotable handle1110rotatably coupled to a side surface1120of the cap1100. The pivotable handle1110including a top beam1112, a pair of side beams1114, and a pair of pins1116. The handle is configured so that the cap1100and bottle1020may be carried by a person using a hand to grip the top beam1112. Top beam1112extends transverse to the longitudinal axis of the cap and operatively attaches to the pair of side beams1114. Side beams1114are rotatably coupled to a pair of pins1116extending from a side surface1120of the cap1100. Pins1116may be affixed to the cap with a fastener (not shown) or may be integrally formed with the shell1122. Side beams1114are configured to rotate about the pins1116. The top beam1112may be curved in some versions and may directly couple to the pins1116.

FIG. 23shows an illustrative top-down perspective view of illustrative sanitization cap1200with a fixed handle1210fixedly coupled to a side surface1120of the cap1200. Fixed handle1210includes a top beam1212and a pair of side beams1214. Top beam1212operatively connects to the side beams1214, and the side beams1214fixedly connect to the side surface of cap1200. In some versions, top beam1212is curved and directly connect to the side surface1220of the cap1200. In yet other versions, side beams1214are integrally formed with the shell1222.

FIG. 24shows an illustrative top-down perspective view of illustrative sanitization cap1300with an integrally formed handle1310attached to a top surface1330of the cap1300. Integrally formed handle1310is formed of the same material as the shell1322and extends distally along longitudinal axis LA from the top surface1330of the cap1300.

FIG. 25shows an illustrative bottom-up plan view of illustrative sanitization cap1600including a pair of UV-C LEDS604. Like a single UV-C LED604, the pair of UV-C LEDS604when activated may be used to shine UV-C rays into water bottle1020. The UV-C rays may be used to sterilize the contents of the bottle1020. Using more than one UV-C LEDS604reduces the thermal load on the UV-C LEDS604and provides the same radiant flux output as a single UV-C LED604, but the pair of UV-C LEDS604will are configured to be operated at a reduced radiant flux output which create less heat rise thereby exponentially reducing the failure rate of the UV-LEDS604.

FIG. 26shows an illustrative bottom-up view of illustrative sanitization cap1700including a plurality of UV-C LEDS604to maintain the same radiant flux output and even further reduce the failure rate of the plurality of UV-LEDS604. The present example shows five UV-C LEDS604but any number of UV-C LEDS604sufficient to sterilize the contents of the bottle1020and further reduce the failure rate of the UV-LEDS604may be utilized.