Patent Grant
12043357
The present disclosure relates to the field of diving masks, for example masks used for snorkeling.
Generally, the snorkeler is equipped with a mask for vision and with a snorkel for breathing. The snorkel consists of a tube, the lower end of which is provided with a buccal portion which is received in the mouth of the user, and an upper end allowing both the intake of fresh air and the exhaust of exhaled air.
It is known that such equipment has many drawbacks. First, because breathing through the mouth is not natural, some people find it difficult to breathe orally using a snorkel. Another drawback is that it is not possible to speak underwater when you have a snorkel in your mouth.
Also, the use of this mask-snorkel device is not very comfortable. To overcome this drawback, document FR 3 020 620 proposes a diving mask that allows breathing through the nose and through the mouth.
This diving mask includes: a body provided with a visor and a flexible skirt, said flexible skirt including a partition delimiting an upper chamber for the vision of a lower chamber for breathing, the partition being arranged to bear above the user's nose so that the user's mouth and nose are located in the lower chamber, while the user's eyes are located in the upper chamber, the partition including at least a passage arranged to allow a flow of fresh air between the upper chamber and the lower chamber during a phase of inhalation of the user; a snorkel disposed in the extension of an upper portion of the body, the snorkel comprising at least one air duct; in which the body includes an exhaled air exhaust device which fluidly links the lower chamber with the air duct of the snorkel.
This mask also includes a snorkel provided with several channels and a plate which includes check valves in order to close off the air outlet channels during an inhalation phase, on the one hand, and in order to close off the air inlet channel during an exhalation phase.
More specifically, the upper end of such a snorkel generally includes a valve allowing the closing of the snorkel when it is completely immerged, in order to prevent water from entering the mask.
However, sometimes after being completely immerged, the valve of the snorkel remains in the closed position, even after the user has returned to the surface of the water. In addition, in this case, the mask may also be more difficult for the user to remove by hand.
The present disclosure aims at solving the various technical problems stated above. The present disclosure aims at proposing a diving mask that allows improving the reopening of the snorkel when it comes out of the water after having been completely immerged. The present disclosure also aims at facilitating the removal of the mask from the user's face after the snorkel has been completely immerged.
Thus, according to one aspect, a diving mask including a snorkel with a valve is proposed, the valve including:
Thus, it may be possible to balance the pressure difference which may appear between the inside and the outside of the mask. For example, when the snorkel is completely immerged, such that the valve is in the closed position, the user can create, possibly without meaning to do so, a depression inside the mask by trying to inhale. Such a depression can on the one hand create a suction effect of the mask on the face of the user, which can make the use of the mask unpleasant for the user, and on the other hand hold the valve of the snorkel in the closed position, even when the user pulls his head out of the water. Indeed, the valve generally includes a float which, when the level of the water reaches the upper end of the snorkel, closes off the valve under the effect of the buoyancy and which, when the level of the water goes down, reopens the valve under the effect of gravity. However, in case of depression inside the mask, the float may be held in the closed off position of the valve, thus preventing the user from breathing again as long as s/he has not exhaled in the mask to cancel depression. On the contrary, in the mask according to the present disclosure, the balancing means allows compensating for the pressure difference between the inside and the outside of the mask: this avoids having a depression inside the mask and therefore holding the valve in the closed position when the snorkel is out of the water. Optionally, the balancing means is configured to allow a fluid circulation, in this case a circulation of water and/or outside air, from the outside of the mask to the inside of the mask, when the mask is used by a user and when the closure member is in the closed position.
Optionally, the balancing means is mounted on the closure member.
Thus, the closure member of the valve may integrate the balancing means: the balancing means may then be positioned directly on the member which can close the internal volume of the mask. Such an embodiment may therefore allow creating a fluid connection between the inside and the outside of the mask only when the closure member closes off the valve that is to say only when the valve is in the closed position. Conversely, when the valve is in the open position, the closure member may be not in fluid connection with the interior of the mask, so that the balancing means cannot create a fluid connection between the inside and the outside of the mask.
Optionally, the valve includes a body in which the valve orifice is provided, and the balancing means is mounted on the valve body.
Thus, the balancing means may be mounted at the valve—the device capable of closing the internal volume of the mask. The balancing means may therefore be positioned to be immersed only when the valve is also immersed—in the closed position. This may avoid premature immersion of the balancing means, as long as the valve is not in the closed position.
Optionally, the snorkel includes a wall delimiting the inside of the snorkel relative to the outside, and the balancing means is mounted on the wall of the snorkel.
Thus, the balancing means may be mounted on the snorkel, between the valve and the body of the mask. This may make it possible, for example, when the snorkel includes both an inhaled air intake channel and at least a first exhaled air exhaust channel, to provide the balancing means on the exhaled air exhaust channel in order to avoid possible entry of water through the upper chamber of the mask.
Optionally, the snorkel includes a proximal portion and a distal portion. The snorkel may be on the body of the mask by the proximal portion. The balancing means may be mounted on the wall of the distal portion of the snorkel.
Optionally, the balancing means is mounted on the wall of the distal portion of the snorkel so that the valve is located between the proximal portion and the balancing means. Thus, it may be possible to mount the balancing means above the valve such that the balancing means can still be out of the water when the valve is in the closed position.
Optionally, the mask includes a body delimiting the inside of the mask relative to the outside, and the balancing means is mounted on the body of the mask.
Thus, the balancing means may be mounted directly on the body of the mask—on the immerged portion—when the mask is used. Such an embodiment may make it possible, for example, bring the water into the mask, in case of depression, at the desired location, optionally in the bottom portion of the mask—in the lower chamber of the mask.
Optionally, the balancing means has a tubular shape or is in the form of a hole.
The balancing means may allow a balancing between the internal pressure of the mask and the external pressure. To this end, one embodiment of the balancing means may consist of an opening between the inside of the mask and the outside, in order to allow fluid circulation between the two under the effect of a pressure difference. The opening can thus optionally be in the form of a small-sized hole, a tube or channel.
Optionally, the balancing means has a geometry configured to allow fluid circulation through the balancing means only when the pressure difference is greater than a determined value.
Thus, the balancing between the pressure inside the mask and the outside may occur only when the pressure difference is greater than a given value. This may avoid a possible excessive and unnecessary entry of water inside the mask: on the contrary, water may enter the mask by the balancing means only if the pressure difference is greater than a given value allowing fluid circulation in the balancing means. Such a given pressure difference value may optionally be due to the geometry of the balancing means. Thus, when the opening of the balancing means is particularly small, this may result in a significant pressure loss on either side of the balancing means: it may then be necessary to have a minimum pressure difference on either side of the balancing means to allow fluid circulation through said balancing means.
Optionally, the balancing means also includes a valve element, for example a flexible membrane, configured to allow fluid circulation through the balancing means only when the pressure difference is greater than a determined value.
Thus, the pressure difference required to open the balancing means may result, not only from the geometry of the balancing means, but also from the presence of a valve element in the balancing means. The addition of a valve element may allow for better controlling the pressure difference value necessary to obtain fluid circulation between the inside and the outside of the mask.
Optionally, the determined pressure difference value for which the balancing means is configured to allow circulation of a liquid between the outside of the mask and the inside of the mask, is greater than the determined pressure difference value for which the balancing means is configured to allow air circulation between the outside of the mask and the inside of the mask.
Thus, the balancing of the pressure difference may possibly be done in two stages, when the depression inside the mask is significant: in a first stage, when the balancing means is immersed, the pressure difference will decrease by the entry of water in the mask until the pressure difference reaches the determined value allowing circulation of a liquid through the balancing means, then, in a second stage, when the balancing means is again out of the water, the pressure difference will continue to decrease by the entry of air in the mask until the pressure difference reaches the determined value allowing circulation of a gas through the balancing means. This may limit the amount of water entering the mask under the effect of the pressure difference, while allowing the reopening of the valve and easy removal of the mask by hand by the user when the mask is again out of the water.
Optionally, the balancing means comprises a through channel.
Optionally, the balancing means is mounted in the float which generally has an elongated shape.
Optionally, the ratio of the area of the valve orifice to the area, for example the cross section, of the balancing means is greater than 1. Optionally, the ratio is comprised between 1 and 1,000,000. Optionally, the ratio is comprised between 10 and 100,000. Optionally, the ratio is comprised between 100 and 10,000.
It is understood that the balancing means is not intended to allow fluid circulation with a flow rate similar to that of the valve. The balancing means is provided, or configured, to decrease a pressure difference, not to allow the user to continue to breathe normally when the valve is in the closed position. Thus, the balancing means has a flow rate that allows a pressure balancing but which is lower than that of human breath. The user will be able to realize, in use, the closure of the valve, while having a pressure inside the mask which differs little from the one outside.
Optionally, the mask includes a body delimiting the inside of the mask relative to the outside, the body including:
Optionally, the snorkel has an inhaled air intake channel and at least a first exhaled air exhaust channel, said snorkel being the extension of an upper portion of the frame, the inhaled air intake channel opening into the upper chamber while the first exhaled air exhaust channel communicates with the lower chamber, and wherein the first duct of the frame has an upper end opening into the exhaled air exhaust channel.
According to another aspect, a snorkel for a diving mask as described above is also proposed, the snorkel including a valve including:
The body 2 comprises for example a frame 6, a visor 8 and a flexible skirt 10.
The frame 6 is generally oblong with an upper portion 6a and a lower portion 6b, and forms, in use, a banding surrounding the user's face.
The frame 6 may also include a first duct for the exhaled air (not represented) making it possible to convey, at least partly, the air exhaled by the user to the snorkel 4, for example from the lower chamber defined below, and a first duct for the inhaled air (not represented) making it possible to convey, at least partly, the inhaled air from the snorkel 4 to the user, for example to the upper chamber defined below.
The frame 6 finally includes slots 11 intended to receive one or more elastic straps (not illustrated here).
The visor 8 is secured to the frame 6. In this example, the visor 8 is made of a rigid and transparent plastic material, for example polycarbonate.
As can be understood from
Referring to
The visor 8 can also include a purge valve element 12 for the discharge of water which could have entered the mask 1. The purge valve element 12 can be mounted on the visor 8, in its lower portion, on the side of the lower portion 6b of the frame 6.
The skirt 10 is made of a flexible material, for example in a silicone elastomer such as LSR silicone. The skirt 10 is fixed to the visor 8 for example thanks to the frame 6 and is intended to provide the sealing between the inside of the mask 1 and the outside, efficiently and comfortably for the user.
The flexible skirt 10 includes a partition 14 delimiting an upper chamber 16 for vision, and a lower chamber 18 for breathing, the partition 14 being arranged to bear above the user's nose such that the user's mouth and nose are located in the lower chamber 18, while the user's eyes are located in the upper chamber 16.
The upper chamber 16 is in fluid communication with the first duct for the inhaled air of the frame 6, while the lower chamber 18 is in fluid communication with the first duct for the exhaled air of the frame 6.
The partition 14 is fixed to the visor 8 by an added fixing part which is clipped to fixing lugs 20 protruding from an inner face of the domed portion 8b of the visor 8.
The partition 14 includes two orifices which engage with the fixing lugs 20 before positioning the fixing part.
The partition 14 also includes two check valves 22 which are arranged to allow only a flow of fresh air directed from the upper chamber 16 to the lower chamber 18 during a phase of inhalation of the user.
Thus, during an exhalation phase, the exhaled air has the effect of closing the check valves 22, which has the effect of preventing the exhaled air from passing from the lower chamber 18 to the upper chamber 16. The exhaled air will therefore be conveyed from the lower chamber 18 to the snorkel 4 by the first duct for the exhaled air.
During an inhalation phase, the pressure drop which occurs in the lower chamber 18 has the effect of opening the check valves 22, whereby the fresh air can flow from the snorkel 4 to the lower chamber 18 by passing through the first duct for the inhaled air and the upper chamber 16.
The diving mask 1 also includes the snorkel 4, of generally tubular shape, with a proximal portion 4a connected to the upper portion 6a of the frame 6, and a distal portion 4b opposite the proximal portion 4a.
In this example, the proximal portion 4a of the snorkel 4 is mounted on the body 2 of the mask, for example on the frame 6, in a removable manner. The snorkel 4 can therefore be unclipped from the frame 6, which allows reducing the bulk of the mask 1 when the latter is not used.
In the example illustrated in
The snorkel 4 comprises an inhaled air intake channel 42 and at least one exhaled air exhaust channel 44. The inhaled air intake channel 42 and the exhaled air exhaust channel 44 both extend between the proximal portion 4a of the snorkel 4 and the internal chamber 28 of the distal portion 4b. Thus, when the snorkel 4 is mounted on the body 2 of the mask, the inhaled air intake channel 42 of the snorkel is in fluid communication, at the proximal portion 4a of the snorkel 4, with the first duct for the inhaled air of the frame 6, and the exhaled air exhaust channel 44 is in fluid communication, at the proximal portion 4a of the snorkel, with the first duct for the exhaled air of the frame 6.
Furthermore, at the distal portion 4b of the snorkel, the inspired air intake channel 42 and the expired air exhaust channel 44 both open into the internal chamber 28, respectively through check valves 43 and 45 for fluidly linking the internal chamber 28 to the inspired air intake channel 42 when the user inspires, and to the expired air exhaust channel 44 when the user expires.
The internal chamber 28 is delimited on the one hand by the cover 26 and on the other hand by the valve body 36 and by the check valves 43, 45. As illustrated in
The valve orifice 38 allows fluid circulation between the outside and the inside of the snorkel 4, for example between the outside and the internal chamber 28 of the snorkel 4. The closure member 40, for example a float, is mounted movable in translation, in the cage 30, relative to the valve body 36. The closure member 40 has for example an open position (see
The operation is as follows.
When the snorkel 4 is out of the water, the float 40 is in the low position, so that air can flow from the inhaled air intake channel 42 or from the exhaled air exhaust channel 44, to the internal chamber 28 then to the atmosphere via the valve 34 and the openings 32 of the cage 30.
When the snorkel 4 is immerged, the float 40 rises to press against the valve body 36, which has the effect of closing off the valve orifice 38, as a result of which air cannot enter the snorkel 4.
For example, when the valve 34 is closed, the inside of the mask becomes a closed space which can be depressed if the user continues to inhale. A more pronounced crushing of the skirt 10 of the mask (suction effect) is then observed, which can be unpleasant for the user. In addition, the valve 34 can also remain in the closed position once the snorkel 4 has emerged, if the depression inside the mask 1 is greater than the weight of the float 40.
In order to avoid such drawbacks, the mask 1 according to the present disclosure includes a balancing means 46. As illustrated in
In order to limit the entry of water into the mask 1, the through channel 47 of the balancing means 46 has a cross section much smaller than the area of the valve orifice 38. For example, the ratio of the area of the valve orifice 38 on the cross section of the through channel 47 may be greater than 1, optionally comprised between 1 and 1,000,000, optionally comprised between 10 and 100,000, optionally comprised between 100 and 10,000.
Furthermore, the balancing means 46 may also comprise a valve element 48, mounted in the through channel 47, and making it possible to create the fluid connection only when the pressure difference on either side of the balancing means 46 is greater than or equal to a determined pressure.
Alternatively, or in addition, the shape of the balancing means 46, for example its shape factor such as the ratio of the cross section to the length of the through channel 47, can also allow introducing a minimum pressure difference on either side of the balancing means 46 in order to obtain a fluid connection.
Thus, the balancing means 46 allows limiting the pressure difference that may exist between the inside and the outside of the mask 1, by allowing an entry of fluid (air or water) inside the snorkel 4, under the effect of the existing depression, when the valve 34 is in the closed state.
It should be noted that the figures represent only one embodiment of the present disclosure, in which the balancing means 46 is mounted on the closure member 40 of the valve 34. However, the present disclosure is not limited to this single embodiment, but also covers its variants.
Thus, the balancing means can be mounted on the body 36 of the valve 34, for example in the form of a hole, possibly with a valve element, positioned next to the valve orifice 38 and allowing the entry of fluid from outside in the internal chamber 28.
Alternatively, the balancing means can be mounted on the cover 26, so as to create a fluid connection between the outside and the internal chamber 28. In the latter case, it can be noted that the balancing means may allow the entry of air in the snorkel 4 if only the valve 34 is immerged, but not the entire cover 26.
Alternatively, the balancing means can be mounted on the wall 24 of the snorkel, in the proximal portion 4a, optionally between the outside and the exhaled air exhaust channel 44, so that water which can enter the mask 1 via the balancing means is found in the lower chamber 18 of the mask and not in the upper chamber 16.
Alternatively, the balancing means can be mounted on the body 2 of the mask, for example on the visor 8, in the bottom portion next to the purge valve element 12.
Thus, thanks to the balancing means according to the present disclosure, it may become possible to limit the pressure difference between the inside of the mask and the outside, when the valve is in the closed position. This may avoid a potential of blockage of the valve in the closed position when the mask is out of the water, as well as the difficulties in removing the mask by hand by the user, while limiting and controlling the possible amount of water entering the mask. The mask may thus become more comfortable and more pleasant to use, while providing the same functions and advantages as previously.
| Number | Date | Country | Kind |
|---|---|---|---|
| 1902284 | Mar 2019 | FR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/FR2020/050440 | 3/5/2020 | WO |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2020/178529 | 9/10/2020 | WO | A |
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| Number | Date | Country |
|---|---|---|
| 205872407 | Jan 2017 | CN |
| 206087242 | Apr 2017 | CN |
| 107399417 | Nov 2017 | CN |
| 108284931 | Jul 2018 | CN |
| 207826506 | Sep 2018 | CN |
| 208134586 | Nov 2018 | CN |
| 208412071 | Jan 2019 | CN |
| 3434578 | Jan 2019 | EP |
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| Entry |
|---|
| Machine English translation of RU2000109694. |
| English language abstract of WO2018027903. |
| English language of KR101076701. |
| English translation of CN205872407U. |
| English translation of CN108284931. |
| English language abstract of CN207826506U. |
| English translation of CN208134586U. |
| English translation of CN208412071U. |
| Number | Date | Country | |
|---|---|---|---|
| 20220135193 A1 | May 2022 | US |
