The present invention relates to the field of emergency flotation devices, especially for use in prevention of deaths due to drowning.
Drowning is a major cause of death worldwide, claiming the lives of more than 300,000 people every year. Many of the drowning events occur in natural waters such as the sea and lakes in the absence of a supervising life guard, and many would have been preventable with use of a personal flotation device.
The prior art describes bracelets, armbands, and other inflatable devices designed for emergency use. Some prior art describes devices that use release of a pressurized gas to inflate such devices. For example, DE 202012007732 to G. Schmelzer for “Rescue bracelet or water airbag for bathers or swimmers users are swimmers such as children, young people of all ages, adults, seniors” describes a bracelet having a capsule and a balloon. Upon activation, pressurized air from the capsule flows into the balloon causing it to inflate. Likewise, WO 2014/077728 to P. P. Mukhortov for “Life-saving wristband” describes a wristband having a system for filling an inflatable elastic buoyance chamber with a gas, such as from a compressed air vessel. DE 202005001471 to P. Tangermann for “Arm-worn marine or swimming pool survival floatation aid has hand-operated inflation trigger grip” describes an armband having a “container for an inflatable bladder” that is “linked to a gas cartridge and activation line” (EPO translation). Activation of this device allows compressed air from inside the gas cartridge to escape into the empty bag and inflate it. Such devices have the disadvantage that a cartridge or vessel of compressed gas needs to be sturdy enough to withstand the pressure of the gas, and hence is expected to be of additional weight and volume.
Other prior art devices use chemical reactions that produce gas to inflate the device. For example, U.S. Pat. No. 7,267,509 to W. H. Jackson III for “Floatation device” describes use of “different chemical reactions that can be used to produce a large amount of gas in a short period of time” such as adding an electrical impulse to sodium azide (NaN3), or fracturing high pressure carbon nanotubes. CN 202670079 to H. Wang for “Bracelet-shaped water self-rescue device” describes a bracelet having “a main container 2 in which a liquid reactant 3 is stored, which is made of an elastic material; [and] a secondary container 7 in which a solid reactant 6 is stored.” “The auxiliary container is communicated with the main container through a through hole” and activation via a pull ring allows the solid and liquid reactants to mix and create a gas. CN 103693180 to R. Jing for “Self-aid wristband convenient to carry” describes a self-aid wristband having “thin film spacers in the radial direction of the hand ring” which can be torn to activate generation of gas and inflation of the wristband.
In all of these prior art devices, the compartment or inflatable bladder has a dual function of storing one or more reactants and of becoming inflated with the gas product. This arrangement has a major disadvantage in that it may not allow full utilization of the reactants, or full completion of the chemical reaction, since some of the reactants may become dispersed by the gas during its generation and hence not used in generating further gas, or some of the reactants may become trapped in crevices within the bladder, or the reactants may be not be in close enough contact, such as positioned at opposite sides of a compartment, or the reactants may not completely mix. In addition to being a potentially inefficient system, it may also have a large amount of variation in the amount of gas produced because it is unpredictable what quantity of the reactants will be available for the chemical reaction. Another disadvantage of such a dual function arrangement is that it may present a higher risk in the event of a failure, such as a leak, since dangerous compounds, such as “highly reactive and potentially explosive” sodium described in U.S. Pat. No. 7,267,509, may be present in the bladder. Furthermore, in some of these chemical reactions described, additional energy input is needed in addition to the reactants and a simple activation mechanism, such as in the case of the electrical impulse described in U.S. Pat. No. 7,267,509, making the device more complex and also increasing risk. Finally, in some of the chemical reactions described, it may be necessary to add additional chemicals not needed for the production of gas, such as in U.S. Pat. No. 7,267,509 in which “other chemicals are added, such as silicon oxide, to react with the sodium to reduce it to a harmless material since sodium is highly reactive and potentially explosive.” The addition of chemicals not needed in the production of gas increases the cost and complexity of the device, and makes the device more prone to failure.
In a life saving device, the efficiency, simplicity, consistency of performance, and fail-safe abilities of the device are critical, since a lack of gas produced or a malfunction may cost a person his life.
There therefore exists a need for a reliable and easy-to-use emergency floatation device, which overcomes at least some of the disadvantages of prior art systems and methods.
The disclosures of each of the publications mentioned in this section and in other sections of the specification, are hereby incorporated by reference, each in its entirety.
The present disclosure describes new exemplary systems for emergency flotation devices, having a novel double-chamber structure, comprising a first chamber in which the chemical reaction takes place, and a second inflatable compartment. The use of a separate chamber in which the chemical reaction takes place, allows full or essentially full completion of the chemical reaction, without the reactants being allowed to disperse. Unlike the devices having a dual function compartment described in the prior art, in which both the reaction and inflation take place in the same compartment, the presently disclosed systems have a separate reaction chamber and a separate inflatable compartment, each of which is constructed to efficiently fulfill its own dedicated function. The gas-tight inflatable compartment is generally the outer compartment and the reaction chamber is generally disposed within the outer compartment, to contain and protect the reactants, increasing safety of the device. However, in alternative implementations, the reaction chamber may be provided on the outside of the device, peripheral to the inflatable compartment, preferably with concomitant safety measures in place to prevent leakage of the reactants out of the device.
The chemical reaction chamber, generally the inner compartment, is a closed volume in which the reagents are constrained from exiting the reaction chamber, thereby being kept in contact during the reaction, in order to allow the full completion, or essentially full completion of the reaction. This structure provides a maximum yield of gas from the reactants, allowing a smaller volume of reactants to be used, thus decreasing the size and increasing the convenience of the wearable device. In addition, since it is expected that there will be maximum yield from the chemical reaction, the device consistently produces the same amount of gas and the user may feel secure that there will be adequate gas output in the event of an emergency.
The extent of the term above—essentially full completion of the reaction—is dependent on the particular design and intended usage of the device. Optionally, the device should enable full completion of the reaction, such that maximum use is made of the reactants, and the maximum amount of inflation gas is generated. However, since the ideal of complete usage of the reactants will generally not be achievable, a compromise construction must be used to maximize the practical use of the reactants. Thus, if speed of deployment of the flotation device is the primary aim, then the outflow of a larger part of the reactant solution before the reaction has been completed can be tolerated. On the other hand, if minimum weight and compactness of the device is the primary aim, then more of the reactants should be contained within the reaction chamber before the exit passageway opens, to allow the maximum possible yield of inflation gas. Thus, the term “essentially full completion of the reaction” could be 95% of the reaction, or 90%, or 80% or only 70%, or even less, depending on the specific requirements of the device. The person of skill in the art will be able to design the flotation device to achieve the required specification in this respect, all of such designs relying on the common feature of maintaining the reactants in a reaction chamber separate from the inflation chamber until as much of the reactants as possible can be used to generate gas.
Essentially full completion of the reaction is enabled by use of a dedicated passageway between the reaction chamber and the inflatable compartment, which has a number of special properties which ensure the functionality of the device. There are two different approaches by which this can be achieved, with the device using either or both of the methods. The approach used, and hence the constructional features of the device, is dependent on the particular reactants used, or more particularly, on the speed with which the reaction takes place. In both of the approaches, the exit aperture from the reaction compartment to the inflation chamber is implemented as a pressure sensitive, one-way passage, such that it only opens in the preferred direction of opening, and only when the internal pressure within the reaction chamber has reached a predetermined level, causing the passageway to open. Under those circumstances, the passage from reaction chamber to the inflation chamber opens only when sufficient gas has been generated to increase the pressure sufficiently to open the passageway valve. According to the situation when the reactants and their physical form are such that the reaction takes place quickly, the gas is generated in a time which is short compared with the time taken for the reactant solution to leak out through the passageway from the reaction chamber, this minimizing any residual transfer of reactants before the reaction is in its advanced stages. Then it is sufficient that the passageway should be uni-directional and pressure sensitive. In such a case, gas may flow from the reaction chamber to the inflatable compartment, but essentially not back, only when a sufficient pressure has been generated in the reaction chamber. This minimizes any residual transfer of reactants before the reaction is in its advanced stages.
On the other hand, if the reaction is slow, such as for instance if it is necessary to dissolve solid components of the reactants in water before the action can commence, then the passageway should be such that there is significantly easier passage of the gas out of the reaction compartment, as compared with the liquid reactants, or as compared with the solution resulting from the addition of water to solid reactants. This ensures that the reactants are kept within the reaction chamber for as long as possible while the reaction is taking place, thus ensuring full completion of the reaction. The dedicated passageway may be described as providing substantially preferential passage of the gas over the liquid reactants. This means that while passageways in general naturally provide preference of the passage of gases over the passage of liquids, due to the molecular properties of these different phases and their respective viscosities, the passageways described in the present disclosure are constructed such that this effect is amplified above what a conventional orifice, slit or passage would provide.
The dedicated passageway may be, for example, an airway, a valve, or a membrane that allows gas to pass, without allowing any significant amount of the chemical compound solution to pass. The gas permeable membrane solution may be implemented by constructing the walls of the reaction chamber of that membrane material, thereby providing a sufficiently large transfer surface to enable the membrane to achieve its filtering function within a reasonable time scale.
One example of a passageway for use in such devices could be a uni-directional, pressure sensitive, duckbill valve positioned between the reaction chamber and inflatable compartment, such a valve having all of the above described special properties. Such a duckbill valve may be structured to only open at a predefined minimum pressure, which would only be achieved when the reaction is in the advanced stages, and at these stages there is virtually no remaining liquid reactant solution. In that respect, such a passageway would fulfill its function regardless of the speed of the reaction.
Relating now to the chemical reaction used to generate gas for inflation of the device, in one particularly advantageous implementation, use is made of an acid and a base that generate gas upon reacting, but other suitable gas generating reactants may be used. The reactants may be in solid form, such as crystals or powder, in which case saline or fresh water may be used as an additional component, which may conveniently be obtained from water surrounding the user while swimming. In other implementations, a desired amount of water may be provided in a designated chamber during manufacture of the device. Alternatively, an acid may be provided as an acidic solution, or a base may be provided as an alkaline solution, or both, such that the addition of water may not be necessary.
The inflatable component, generally the outer compartment, should be a sealed, gas-tight compartment designed to collect the gas produced from the chemical reaction occurring in the reaction chamber. When the inflatable compartment inflates, it allows the swimmer to be supported such that his head can remain above the water.
Activation of the device starts the chemical reaction by mixing the reactants. The gas produced from the chemical reaction then emerges from the reaction chamber to the inflatable compartment through the designated one-way, pressure sensitive passage. Since the reactants, some of which may be potentially harmful to human contact, are kept in the reaction chamber, generally in an inner protected chamber, and the inflatable chamber should contain only gas, the presently disclosed devices provide increased safety over prior art devices. For example, in the event of a leak in the outer wall of the inflation compartment of the device, only gas would be expelled, and there would not be a significant risk of human contact with potentially harmful chemicals or compounds, such as acid.
In a further advantageous implementation, the reaction chamber may be equipped with a one-way valve for bringing in a predetermined amount of water surrounding the user, such as sea water, to be used in the gas producing chemical reaction. This minimizes the amount of acid and base reactant needed, allowing the device to be light-weight. The reactants may be provided in solid form, and the entire volume of water needed for the reaction may be provided from water surrounding the user in this manner. Alternatively, the acid may be provided as a concentrated acidic solution, and a base may be provided as a concentrated alkaline solution, or vice versa, and then water may be drawn in to the device while the user is swimming to dilute either or both of the solutions.
The presently disclosed devices are designed to be light-weight and their structure is configured so that it does not interfere with swimming motion prior to activation. Such devices may be conveniently and quickly activated by a user with a manual trigger, such as a handle, a cord, or a similar device. Alternatively, they may be activated by an automatic sensor, such as a depth sensor or a pressure sensor, to initiate the chemical reaction and inflation. Such automatic activation may use electric or ultrasound sensors, and may comprise a time delay feature to differentiate between swimming and drowning, such that the device only becomes activated when the sensor is below water level for a predetermined time duration. Generally, the implementations comprising automatic sensors also comprise a manual activation option for increased safety.
The presently disclosed flotation devices are wearable or easily portable, light-weight, disposable, inflatable devices designed for use in emergencies to prevent drowning by supporting the user such that the user may float with his head above the water level.
There is therefore provided, in accordance with an exemplary implementation of the devices described in this disclosure, an inflatable flotation device comprising:
(i) a reaction chamber comprising reactants that generate gas when mixed, the reactants being separated by a barrier assembly,
(ii) an activating mechanism adapted to either remove or to puncture the barrier assembly such that the reactants mix, and
(iii) an inflatable compartment fluidly connected to the reaction chamber by means of at least one pressure sensitive passageway, adapted to open only when the pressure of the gas in the reaction chamber exceeds a predetermined threshold.
In such an inflatable flotation the predetermined threshold may be selected such that the reaction between the reactants is essentially complete before the at least one pressure sensitive passageway opens, such that the reactants are kept within the reaction chamber until the reaction is essentially complete. The at least one passageway may further be adapted to provide substantially preferential passage of the gas over the reactants, such that the reactants are generally contained within the reaction chamber until the reaction is essentially complete. The at least one passageway may most conveniently be a valve, and should be one directional towards the inflation chamber. Alternatively, the at least one passageway may be a semi-permeable membrane preferentially enabling passage of gases over liquids. In any event, the at least one passageway should be sufficiently small that it allows substantially preferential passage of the gas over the reactants.
In further exemplary implementations of the inflatable flotation devices of the present disclosure, the reactants may comprise an acid or acidic solution and a base or alkaline solution, and optionally, water. Additionally, at least one reactant may be in a non-aqueous state. Furthermore, the reactants may comprise a volume of less than 80 milliliters and generate at least 5 liters of gas.
In yet other implementations, the barrier assembly may be a sheet and the activating mechanism a pointed element adapted to puncture the sheet. The activation mechanism may comprise a manual trigger, and that manual trigger may be at least one cord attached to the barrier assembly. Additionally, the barrier assembly may be comprised of a decomposable material that disintegrates or dissolves when exposed to the gas.
Even more implementations of the inflatable flotation device may further comprise a sensor indicative of immersion in water for more than a predetermined time, and providing a signal to activate the inflation device.
Finally, for any of the above described implementations, the barrier assembly may comprise at least one of a removable cap, a removable layer, a blister pack, a tube and a clamp.
There is further provided according to yet another implementation of the inflatable flotation devices of the disclosure, an inflatable flotation device comprising:
(i) a reaction chamber comprising reactants that generate gas when mixed with water,
(ii) an activating mechanism adapted to expose the reactants to water, and
(iii) an inflatable compartment fluidly connected to the reaction chamber by means of at least one pressure sensitive passageway, adapted to open only when the pressure of the gas in the reaction chamber exceeds a predetermined threshold.
Such an inflatable flotation device may further comprise a water inlet valve connecting the reaction chamber to the ambient water environment of the device, such that the reaction chamber can be filled from ambient water surrounding the device when the water inlet valve is open. Such a device may further comprise a separate compartment of the reaction chamber, the activating mechanism being adapted to expose said reactants to water by enabling water disposed in said separate compartment to mix with said reactants in said reaction chamber. Additionally, the device may further comprise a water inlet valve connecting the separate compartment to the ambient water environment of the device, such that the separate compartment of the reaction chamber can be filled from ambient water surrounding the device when the water inlet valve is open.
In any of the above described inflatable flotation devices, the predetermined threshold may be selected such that the reaction between the reactants when mixed with water is essentially complete before the at least one pressure sensitive passageway opens, such that the reactants are kept within the reaction chamber until the reaction is essentially complete. The at least one pressure sensitive passageway may further be adapted to provide substantially preferential passage of the gas over the reactants, such that the reactants are generally contained within the reaction chamber until the reaction is essentially complete. Additionally, such inflatable flotation devices may further comprise a passageway between the separate compartment of the reaction chamber and the section of the reaction chamber containing the reactants, wherein the activating method opens the passageway such that the water can mix with the reactants. Furthermore, in any of these implementations, the water inlet valve may be actuated by the actuating mechanism.
According to yet another implementation, in these inflatable flotation devices, the separate compartment may further comprise a water outlet valve, such that the separate compartment can be emptied of water.
Additionally, these devices may further comprise a sensor indicative of immersion in water for more than a predetermined time, and providing a signal to activate the inflation device. In such a case, the sensor may be adapted to detect any one of vibration, depth, pressure or light.
Finally, in any of these implementations, the reactants may be solids.
The present invention will be understood and appreciated more fully from the following detailed description, taken in conjunction with the drawings in which:
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For a typical adult sized inflation chamber, the current device may hold approximately 75 ml of acid, base, and water which should allow the creation of 5 to 7 liters of gas. The corresponding weight of about 75 g can easily be carried by most swimmers, yet provides a sufficient amount of gas for adequate inflation capabilities in the event of need.
The inflatable chamber 11, generally the outer compartment, is sealed and designed to contain the gas originating from the chemical reaction occurring in the inner device. When the inflatable compartment inflates, it supports the swimmer such that his head can remain above water. It is to be understood that the term “inflatable chamber” may be a single component or may comprise multiple fluidly connected sections for increased comfort such as is typical in wearable flotation devices. However, in such a case of a device having multiple sections, it is to be understood that these sections are configured to be inflated with gas and that none of these sections comprise any reactants, nor does the chemical reaction occur in any of these sections.
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In this implementation, the device may be activated manually, such as by pulling a cord 60, which may be attached to the pointed element 58, or to a structural part of the reaction chamber to which the pointed element is attached. One of the sub-compartments may contain a liquid reactant, such as an acidic solution, and the other may contain a solid or aqueous solution of the second reactant, which in this example would be a gas producing base.
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There are a two possible implementations of the device, depending on how it is intended to be used. According to a first, and probably more convenient implementation, the activation trigger causes two separate actions to occur. Valve V1, which enables entry of the sea or fresh water into the water container 82, is opened, thereby charging the reaction chamber with water, and at the same time valve V3 is opened, thereby allowing the water charge to mix with the dry reactants and to generate the inflation gas. This implementation has the advantage that until activated, the device does not contain any water, thereby contributing to its lightweight and convenient form.
According to a second implementation, the water entry valve V1, is activated by the user as soon as he/she enters the water, such that the water charge is ready for use in case of an emergency. Activation then only involves opening valve V3 to allow the pre-charged water to mix with the dry reactants and to generate the inflation gas. This implementation, though less convenient, since the swimmer has to wear the device with its water charge, even though that charge is only on the order of 75 g, has the advantage that the water charge can be collected at a time when no emergency is being experienced, such as when entering the sea to swim. In that case, the user has sufficient presence of mind to ensure that the water intake opening is below the water level of the sea. This may not be so certain with the previous first implementation, where water intake is only performed when the activation mechanism is triggered at the time of an emergency. An optional additional valve V2 may be located on compartment 82 for draining the water charge from the device when the user has finished swimming. Therefore, if the reaction has not been activated, draining of the water charge from the device through valve V2, enables the device to be dried out and used again.
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In any of these implementations, a depth sensor or pressure sensor (e.g., an ultrasonic sensor) may be connected to the inflation device, such that when the sensor reaches a predefined depth, it automatically activates the inflation device. This enables automatic activation of the device if the swimmer sinks into the water. Alternatively or additionally, any suitable simple manual activation mechanism, such as a lanyard, a handle, a lever, or tearing a seal, may be used to initiate a chemical reaction, thus activating the device.
It is appreciated by persons skilled in the art that the present invention is not limited by what has been particularly shown and described hereinabove. Rather the scope of the present invention includes both combinations and subcombinations of various features described hereinabove as well as variations and modifications thereto which would occur to a person of skill in the art upon reading the above description and which are not in the prior art.
This application is a U.S. National Phase Application under 35 U.S.C. 371 of International Application No. PCT/IL2018/051314, which has an international filing date of Nov. 29, 2018, and which claims priority and benefit from U.S. Provisional Patent Application No. 62/591,787, filed Nov. 29, 2017, the contents and disclosure of which are incorporated herein by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/IL2018/051314 | 11/29/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/106677 | 6/6/2019 | WO | A |
Number | Name | Date | Kind |
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1240686 | Luca | Sep 1917 | A |
4781645 | Kato | Nov 1988 | A |
5941752 | Liebermann | Aug 1999 | A |
20030236040 | Miller | Dec 2003 | A1 |
Number | Date | Country | |
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20200407031 A1 | Dec 2020 | US |
Number | Date | Country | |
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62591787 | Nov 2017 | US |