EP3930522A1 - Inflatable device for the protection of objects or persons - Google Patents

Abstract

The invention relates to a device (1) for protecting an object or a person, comprising a sealed elastic membrane (2) provided for receiving a gas and a fibrous envelope (3) containing said membrane (2): in the inoperative state, the membrane (2) has a different size from that of the envelope (3) and the envelope (3) containing the membrane (2) can be folded; in the operative state, the membrane (2) has a size corresponding in shape to that of the envelope (3), the membrane (2) then occupying a first volume corresponding to the maximum volume of the envelope (3), the envelope (3) being intended for retaining an expansion of the volume of the membrane (2) beyond the maximum volume of the envelope (3), referred to as second volume, said envelope (3) being intended for adopting a shape that fits the object or person to be protected, in the unconstrained state, the membrane (2) can occupy a third volume larger than the maximum volume of the envelope (3).

Description

DESCRIPTION

INFLATABLE OBJECT OR PERSON PROTECTION DEVICE

The present invention relates to the field of devices for protecting objects or people. More particularly, the invention relates to such inflatable protection devices.

In the field of the protection of cyclists or of people using new modes of urban transport such as, for example, electric scooters, protective helmets are already known which are necessary, or even compulsory, for the protection of the head.

The structure of currently known helmets varies according to their destination and is therefore more or less elaborate.

Most of these helmets have separate superimposed layers which are intended to cushion impact and provide mechanical strength to the helmet.

Generally, these helmets are relatively heavy, bulky, with a one-piece outer shell to guarantee protection and safety, to the detriment of the aesthetic appearance and the comfort sought by the user.

The transport in an urban environment of such a helmet by its user is thus heavy and bulky.

In the field of industry, it is often necessary to transport parts or finished products from a first physical place of manufacture to a second physical place of assembly. This is particularly the case in the field of space, aeronautics or the automobile.

In the field of space or aeronautics, the production of a meticulous part forming part of the final object to be produced can be manufactured in a site remote from another assembly site. Its transport must be rigorous so as to avoid any deformation or impact that could make this meticulous part non-compliant with receipt. To transport such parts, it is known to use a transport box generally formed of wood and in which a careful part is placed while being surrounded by foam chips for its protection.

Although such transport cases generally ensure the transport of the precious part in complete safety, they have the drawbacks of being bulky, poorly suited to said part transported and not reusable. In the automotive field, during vehicle transport from their assembly site to their final delivery location, it is known practice to spray paraphine foam on the vehicles to be transported in order to avoid any impact that could damage their bodywork. However, such a foam requires a removal operation thereof in order to remove it from the delivered vehicle. Furthermore, such a foam cannot be reused.

The present invention relates to an improved object or person protection device overcoming the aforementioned drawbacks while ensuring the protection of the object or the person.

To this end, the invention relates to a device for protecting an object or a person, the protection device comprising at least one waterproof elastic membrane provided to receive a gas and at least one fibrous envelope containing said membrane:

in the resting state of the protection device, the membrane is of dimension different from that of the envelope and the envelope containing the membrane can be folded, in the active state of the protection device, the membrane is of dimension in correspondence in shape with that of the envelope, the membrane then occupying a first volume corresponding to the maximum volume of the envelope, called the second volume, the envelope being designed to retain an expansion of the volume of the membrane beyond the maximum volume of the envelope, said envelope being designed to take a shape adjusting to the object or person to be protected,

and, in the unconstrained state, the membrane can occupy a third volume greater than the maximum volume of the envelope.

Such a protection device allows a reduced size in the deflated and folded rest state, and a mechanical protection comparable to the rigid protection devices in the active state of the protection device.

It will be understood that in the unconstrained state by the envelope, when it occupies a volume corresponding to the first volume, the membrane assumes a random form which is not plastically stressed.

Furthermore, such a protection device offers shock absorption and distribution properties by using the mechanical properties of the gas, by deformation of the structure on impact in the active state of the device.

In the active state, the device guarantees mechanical protection of the object or part of the body to be protected against the risk of impacts from its environment by a appropriate volume and pressure, and which are achieved by constraint during the volume setting by inflation of the membrane and by mechanical resistance of the envelope.

In the active state of the protection device, the casing forms a rigid frame made possible by the inflated state of the membrane shaped by the mechanical stressing in the casing to give the final shape to the protective device advantageously designed for adjust to the object or part of the body to be protected.

In fact, the properties of the material of the envelope combined with the properties of the material of the membrane give the device mechanical properties that are different from the mechanical properties of the envelope and of the membrane taken separately.

Advantageously, the shape and dimensions of the protection device in the active state are repeatable. Preferably, control elements for the expansion of the protection device allow the shape and dimensions of the protection device to be repeated. These expansion control elements can be a strap, the fibrous envelope itself or any additional fabric, a wedge, a loop or even a net.

The repeatability of the shape and dimensions of the protective device in the active state advantageously ensures constant maintenance of the mechanical response of the protective device in the event of an impact.

Advantageously, the protection device and its constituent elements are designed for use of at least 400 inflation or deflation cycles.

In the active state of the protection device, the pressure of the membrane is chosen to meet the protection requirements of the object or of the person.

In particular, the pressure is between 1 bar and 30 bars. In a particular application to personal protective helmets, the pressure may be between 2 bars and 6 bars.

This pressure corresponds to a nominal pressure of use.

Advantageously, the use tests are carried out at 120% of the nominal working pressure.

Advantageously, the fibrous envelope is a textile coating.

Advantageously, the envelope is made of a textile material made of fiber of high mechanical strength in tension, such as polypropylene or even polyester.

According to another advantage, the protection device comprises two superimposed fibrous envelopes. According to one embodiment of the invention, in the rest state of the protection device, the membrane has a shape that is distinct from the envelope.

According to another embodiment of the invention, the protection device comprises at least one valve.

A sealed system can advantageously allow a sealed assembly of the valve.

Such a sealed connection system for a valve advantageously comprises a lower part and an upper part taking the membrane together and assembled in a sealed manner to one another.

The lower part and the upper part are designed to trap the outline of an opening formed in the membrane so as to make it watertight.

This opening allows the insertion of the valve.

Such a sealed assembly can be achieved by screwing, optionally supplemented by a seal, by welding or even by glue.

The valve is advantageously made of butyl. Such a valve allows inflation by stitching the valve, for example with an inflation needle type tip.

Advantageously, the lower part and the upper part are made of a semi-rigid plastic material so as not to risk injuring the user.

According to another embodiment of the invention, a self-percussing valve allows the control of the quantity of gas injected into the membrane.

The self-impacting valve makes it possible to inflate the protection device using a gas cartridge opened by a mechanical operation consisting in striking the opening of this cartridge.

Advantageously, a striker separate from the valve can be provided.

The striker may comprise a main body which can be partially inserted into the opening of the upper part of the sealed connection system in order to access the valve, a radial stop advantageously extends radially from this body to block the rotation of the striker when a search cartridge is to be targeted.

A needle can extend from this body to allow inflation or deflation of the membrane.

The upper part of the waterproof connection system may include a projection to block the rotation of the radial stop. In an application to a protective helmet, such a striker can be attached to the helmet by a simple wire link.

Advantageously, the valve is configured to support an adapter making it possible to inflate the membrane using a pump.

Advantageously, the valve is configured to support a deflation device which makes it possible to keep this valve open during the deflation operation.

According to an alternative embodiment of the invention, the envelope and / or the membrane comprises a marker corresponding, to the rest state of the protection device, to a witness of a deflated state of the membrane and, to the active state of the protection device, to an indicator of an inflated state of the membrane to occupy said first volume.

Advantageously, the indicator of the deflated state of the membrane corresponds to a first color formed by the unstressed fibers of the envelope and / or of the membrane and the indicator of an inflated state of the membrane corresponds to a second color formed. by the strained fibers of the envelope and / or the membrane.

According to another variant embodiment of the invention, the envelope comprises folds allowing folding and unfolding which can be repeated each time the protection device is used.

According to one embodiment, the protection device can be equipped with a pressure indicator.

Such a pressure indicator makes it possible to indicate to the user whether the pressure of the membrane is in conformity to ensure the protection of the object or of the person.

According to a first variant embodiment, the pressure indicator comprises a rigid or semi-rigid hollow tube welded to the membrane and fluidly connected to the volume of the membrane by an opening, the tube comprising a piston pushing a gauge forming a pressure indicator.

According to a second variant embodiment, the pressure indicator can be formed by a pressure measurement system using TPMS technology for the acronym “Tire Pressure Monitoring System”. Such a measuring system makes it possible to measure the pressure of the membrane and is well suited to such a protection device.

According to a third variant embodiment, the pressure indicator can be at least one piezoelectric gauge.

Such a gauge can advantageously be glued to the membrane in order to measure its elastic deformation representative of the state of inflation of the membrane. According to a fourth variant, the pressure indicator can comprise a mechanical resistive element linked to the tissue or to the membrane and whose mechanical resistivity changes according to the tension applied to the tissue or to the membrane. The resistive state then indicates the pressure state of the tissue or the membrane.

Advantageously, the membrane comprises in its volume, a dioxygen absorber.

Thus, the use of a dioxygen absorber makes it possible to demonstrate the use of a gas containing dioxygen.

The oxygen absorber can be composed of a powder which reacts chemically with oxygen (4FeC03 + 6H20 + 02 -> 4Fe (OH) 3 + 4CO2).

The absorption of oxygen indicates the use of a gas other than that recommended.

The recommended gas is advantageously composed of a mixture of carbon dioxide and nitrogen.

According to an alternative embodiment, an aluminum ball can be used to make it possible to demonstrate the use of a gas containing dioxygen.

Indeed, the use of a gas containing dioxygen has the effect of forming a thin white layer of oxidation on the aluminum ball.

According to an advantageous variant of the invention, the casing comprises at least one recess making it possible to expel the air present in the casing when the protection device changes from its rest state to its active state.

Advantageously, the envelope comprises a plurality of recesses. Even more advantageously, these recesses are formed at the ends of the envelope or else regularly spaced along the envelope.

Advantageously, the indicator of the deflated state of the membrane corresponds to a marker of the membrane masked by the envelope in the rest state of the protection device and the indicator of the swollen state of the membrane corresponds to this marker of the visible membrane by at least one recess in the casing in the active state of the protection device.

According to an advantageous characteristic of the invention, the membrane can be chosen from a material allowing an elastic elongation of at least 200%.

Advantageously, the elastic elongation is between 200% and 300%. According to an alternative embodiment of the invention, the membrane comprises at least one tensor making it possible to control the expansion of the membrane in order to obtain the desired shape.

Advantageously, the membrane is chosen from the family of polymers.

Advantageously, the elastic membrane is a film of polymer material with a thickness of between 20 microns and 500 microns.

The membrane can be chosen from the family of polymers with a thickness of between 20 microns and 500 microns and allowing an elastic elongation of at least 200%.

In one application of the protective device to a personal protective helmet, the elastic membrane is a film of polymer material with a thickness of between 50 microns and 300 microns.

Preferably, the elastic membrane is a film of polymer material with a thickness of less than 300 microns.

Preferably, the film is a film of urethane polymer material.

According to an advantageous variant of the invention, the fibrous envelope is sewn on its outline. It will be understood that during this sewing operation, the fibrous envelope is arranged in a plane.

Advantageously, the envelope and the seam of the envelope are chosen to ensure mechanical resistance when the device passes from its rest state to its active state.

When the protection device comprises two superimposed fibrous envelopes, the seams of each envelope may be distinct from one another.

According to another aspect, the invention relates to a protective helmet for a person, the protective helmet being formed by a protective device as defined in the present document, and the fibrous envelope is adapted to take the form of '' a protective helmet when the protective device changes from its rest state to its active state.

According to a first application, the protective helmet according to the invention is intended to form a bicycle helmet.

According to a second application, the protective helmet according to the invention is intended to form a motorcycle helmet.

Such a motorcycle helmet can be of the Bol type, that is to say in the form of a half-shell covering the top of the skull or else in the form of a Jet, that is to say in the form of a half-shell. of a half-shell descending to the temples, or else of the integral type, that is to say in the shape of a Jet and covering the face of the head of the wearer of the helmet.

According to a third application, the protective helmet according to the invention is intended to form a sports protective helmet for the prevention of impacts in contact sports such as rugby, martial arts, American football or even football without its use is limiting.

Advantageously, the form of the protection device takes that of a full-face type helmet.

The fibrous envelope may be chosen from a textile material with high mechanical strength in tension and / or in traction.

Advantageously, the fibrous envelope can be made of a high resistance material such as Kevlar or else very high molecular weight polyethylene (UHMPE) which is a high density polyethylene (PE-HD).

The fibrous shell can also be formed from Zilon fiber.

Such a Zilon fiber protector provides good stability and resistance to temperatures up to 600 ° C so that the protector can be well abrasion resistant. Furthermore, such a Zilon fiber device resists bending well and is very flexible.

Advantageously, the fibrous envelope is treated against the penetration of water thanks to a durable water-repellent treatment, the acronym of which is “DWR for Durable Water Repellent” which is applied to the surface of the fibrous envelope during the coating. manufacturing. Such treatment forms a film making the fibrous envelope impermeable.

In an advantageous variant, the fibrous envelope is made of a microporous material and therefore impermeable without additional treatment. Such a microporous material advantageously consists of micropores which are much smaller than a drop of water, approximately twenty thousand times, preventing the drops from passing through the material. Unlike water repellency, waterproofing does not diminish with use and supports any amount of water.

Advantageously, the form of the protection device takes that of a Bol type helmet.

According to an alternative embodiment, the protective helmet comprises an adjustment system making it possible to adapt the protective helmet to the person wearing it.

Advantageously, the adjustment system is formed by tightening straps attached to two separate points attached to the casing. According to an advantageous variant, the protective helmet comprises an occipital support system allowing an optimized holding of the helmet.

Advantageously, the textile is heat-sealable polyester.

Advantageously, the textile is composed of at least part of heat-sealable polyester.

According to an advantageous variant, an additional fibrous envelope covers the assembly formed by the fibrous envelope comprising the elastic membrane.

Advantageously, this additional envelope has mechanical characteristics once stretched which allows impact resistance.

Advantageously, the additional envelope is formed from a fiber having an elasticity of less than 5%.

Advantageously, in the active state of the protection device, the additional envelope is stretched by the elastic membrane.

According to an alternative embodiment of the invention, the protective helmet comprises a visible visor when the protective device reaches its active state.

It will be understood that the visor is formed by a part of the membrane and of the envelope provided for this purpose.

According to one embodiment, the helmet may be equipped with a multilayer hygienic protective sheet which can be successively removed.

Obviously, this protective layer is placed inside the helmet in contact with the user's head.

Such a web allows hygienic single-use use. Indeed, each layer can be torn successively after use of the helmet. In this way, it is ensured for the user to have a perfectly clean helmet when using it.

Such a sheet allows of course the shared use of the same headset by several users.

The layers forming the web can advantageously be biodegradable.

Advantageously, the different layers are linked together by a non-permanent adhesive. These non-permanently bonded layers can thus be repositioned to allow the successive detachment of the layers and to prevent a sticky part from coming into contact with the user's head.

Advantageously, the different layers are linked together by a seam characterized by its direction and its length, making it easier to tear off one layer after another.

Advantageously, the different layers are linked together and then pre-cut at points to facilitate tearing from one layer after another.

Advantageously, the material of the various layers of the web is a biodegradable material with a thickness less than or equal to 45 g / m2.

Advantageously, the material of the different layers of the web can be chosen from the following materials taken alone or in combination: wood fibers, beeswax, or even cellulose fibers.

Advantageously, this sheet is linked to the helmet by a system of quick fasteners such as press studs, Velcro, zippers or even eyelets. Such a quick-attach system allows the replacement of a web no longer comprising a remaining layer by a new web comprising a plurality of layers.

According to one embodiment, the helmet can comprise a damping structure formed with the elastic membrane, the damping structure comprises a network of dampers connected together and designed to be formed in the active state of the protection device. These dampers form interconnected air chambers. These dampers can for example take the form of bubbles.

It will be understood that the network of dampers is fluidly connected to the membrane. Thus, the pressure in the membrane in the active state corresponds substantially to the pressure in each of the dampers of the network.

Such a damping structure is designed to be placed in the helmet, the dampers of the network being oriented towards the user's head.

Such a damping structure makes it possible to limit the risk of concussions that can be caused in the event of impact. This damping structure is in particular more effective in the context of oblique impact.

The shock absorbers can be designed to adapt to the morphology of the user's skull.

These shock absorbers, associated with the deformation properties of the gas, allow better absorption in the event of an impact. According to one embodiment, the helmet can be equipped with a wireless camera attached to the rear of the helmet.

Such a camera allows the user to see the road scene behind him without turning his head and / or letting go of the handlebars.

Such a camera can advantageously be connected by Wifi or by Bluetooth to the user's mobile phone.

Thus, the user can see on his phone screen fixed to his handlebars the road scene behind him.

According to one embodiment, the helmet comprises a fabric storage compartment directly linked to the helmet.

Such a storage compartment allows the object in its inactive state, that is to say deflated, to be stored using its smallest volume.

Advantageously, this storage compartment can be equipped with a closure which may be of the zipper type or with buttonholes, thus making it possible to maintain the helmet in the restricted volume.

Advantageously, this storage compartment is sewn directly to the protective helmet.

Advantageously, this storage compartment is linked to the protective helmet by means of a cord type link.

Advantageously, this storage compartment can be locked by an anti-theft cable.

Such a storage compartment can be applied to the protection device.

According to one embodiment, the helmet can include a signaling system directly integrated on the protective helmet.

Such a signaling system can include night lighting.

By way of example, such a night lighting can comprise a brake light which is activated by virtue of an accelerometer during braking.

Such night lighting can also include indicators that can be controlled by the user via a wireless system positioned on the handlebars.

According to another aspect, the invention relates to a method of assembling a device for protecting an object or a person as defined in the present document. The method comprising the following steps consisting of: a patronage step in which a material forming the fibrous envelope or the waterproof membrane is positioned on an object or the part of the body to be protected in order to determine the protection zones, then these zones protection are projected onto the material to create a two-dimensional plane of the fibrous envelope or waterproof membrane;

a step of welding this membrane;

a step of including a valve of the membrane;

a verification step consisting in measuring an expansion of the volume of the membrane beyond the maximum volume of the envelope.

It will be understood that the step of assembling the membrane by welding and the step of including the valve make it possible to ensure tightness at the desired pressure.

Advantageously, the patterning of the fibrous envelope is such that it makes it possible to have additional material allowing sewing or assembly at certain points with the envelope, reducing the risk of damaging the sealed compartment of the membrane.

Advantageously, the method comprises a sewing step in which two fabrics forming the fibrous envelope containing the membrane are assembled by a peripheral sewing operation.

Advantageously, in order to avoid damaging the membrane during the sewing operation, it is brought together in a restricted space of the fibrous envelope using an element which allows this compacting function and which loses this function, releasing the membrane, from the first inflation.

For example, the membrane can be trapped in an unattached wire or else trapped in a very elastic net. Thus during the sewing operation, the membrane occupies a very small volume and does not risk being pierced, then when the membrane is inflated the first time, the thread is untied or the net extends, leaving the membrane swollen. take up all the available volume.

Advantageously, the method comprising a step of checking the abrasion resistance of the fibrous envelope.

Of course, the fibrous envelope tested can be the additional fibrous envelope.

The purpose of such abrasion resistance is to check the resistance to friction, for example, against the coating of a roadway which may be caused during an accident. Advantageously, the method comprising a verification step consisting in ensuring that over a period of normal use of the device, the pressure remains sufficient to guarantee the protection function.

Advantageously, obtaining the desired shape is ensured by welding or stitching points of the waterproof membrane and of the fibrous envelope.

Such welding or stitching points make it possible to facilitate the shaping of the membrane in accordance with the object or the person to be protected.

Other aspects, aims and advantages of the invention, of preferred embodiments thereof, given by way of non-limiting example, will become apparent on reading the following detailed description and made with reference to the appended drawings in which:

Figure la shows a schematic view of a protection device surrounding an object to be protected and shown in an inactive state,

FIG. 1b represents the protection device of FIG. 1a represented in an active state,

Figure 1c shows a schematic view of a protection device according to the invention without an object to be protected,

Figure ld shows a schematic view of the device of figure the folded,

Figure 2a illustrates a front view of a protective device forming a protective helmet,

Figure 2b illustrates a side view of the protective helmet of Figure 2a,

Figure 2c illustrates a rear view of the protective helmet of Figure 2a,

Figure 2d illustrates a top view of the protective helmet of Figure 2a,

Figure 3 illustrates a front view of a pattern of an envelope of the protective helmet of Figures 2a to 2d,

FIG. 4 illustrates a front view of a pattern of a membrane of the protective helmet of FIGS. 2a to 2d,

FIG. 5 illustrates a first variant embodiment of a protection device shown in FIGS. 3 and 4,

FIG. 6 illustrates a second variant embodiment of a protection device shown in FIGS. 3 and 4,

FIG. 7 illustrates a third variant embodiment of a protection device shown in FIGS. 3 and 4 of an object to be protected. Figure 8 illustrates a schematic view of a section of a hygienic protective mat.

Figure 9 illustrates a schematic view of a section of a damping structure provided with the membrane.

FIG. 10 illustrates an exploded schematic view of a sealed connection system for a valve.

Figure 11 is a schematic view of a valve striker.

Figure 12 is a schematic view of a pressure indicator.

In Figures la to ld, there is shown a protection device 1 of an object. Such a protection device 1 can for example be a cover for transporting a detailed object to be transported, such as a mechanical part in the field of space or aeronautics.

The device 1 for protecting an object comprises a waterproof elastic membrane 2 provided to receive a gas and a fibrous envelope 3 containing said membrane 2.

The envelope 3 is provided to surround the object 4 to be protected.

The envelope 3 is designed to take a shape which adjusts to the object to be protected.

In Figure 1a, the device is shown in an inactive state, that is to say when the elastic membrane 2 contained in the fibrous envelope 3 is deflated.

The fibrous envelope 3 is formed by the assembly of two skins 3 ', 3 between which the membrane 2 is contained.

A first skin is intended to form an outer skin 3 ′ and a second skin is intended to form an interior skin 3 ″.

The inner skin 3 "is that in contact with the object 4 to be protected, unlike the outer skin 3 '.

In FIG. 1b, the protection device 1 of the object 4 is represented in an active state, that is to say corresponding to the inflated state of the membrane where the membrane 2 is of dimension corresponding in shape to that of the envelope 3, the membrane 2 then occupying a first volume corresponding to the maximum volume of the envelope 3, the envelope 3 being provided to retain an expansion of the volume of the membrane 2 beyond the maximum volume of the envelope 3.

According to a particular characteristic of the invention, the outer skin 3 'and the inner skin 3 are formed of a material distinct from each other so that the skin inner 3 '' is formed from an elastic fibrous material while the outer skin 3 'is formed from a weakly elastic fibrous material.

By way of example, the outer skin 3 ′ is formed from a high resistance material such as Zilon fiber and the inner skin 3 ″ is formed from a textile material such as polypropylene or else polyester and which may comprise at least less in part an elastane composition.

It will be understood that the combination of such an outer skin 3 ′ and an inner skin 3 makes it possible to ensure control of the expansion of the membrane 2 when it is inflated while ensuring the matching of shape of this same membrane 2 with object 4 that it must protect. The object 4 to be protected is then kept in the fibrous envelope 3 and the overall volume of the protection device is controlled.

In this way, better protection of the object 4 is ensured during its transport.

In FIG. 1c, the protection device 1 has been shown without the object 4 to be protected and which is shown so as to illustrate its advantageous bulkiness properties. Indeed, the size of the protection device 1 formed of fibrous and elastic material can be advantageously easily reduced to be, for example, placed in a compartment provided for its storage.

Preformed fold lines have also been shown on at least the fibrous envelope 3 so as to facilitate the folding thereof.

In Figure 1d, the protection device 1 is shown in a folded state. In this folded state, the protection device 1 occupies dimensions in length and in width corresponding to one third of those of the protection device 1 in its active state.

In Figures 2 to 7, there is shown a protective device 1 forming a protective helmet 1 of a person.

The helmet according to the invention comprises a waterproof elastic membrane 2 designed to receive a gas and a fibrous envelope 3 containing said membrane 2.

The envelope 3 is designed to take a shape that fits the head of the person to be protected.

In the active state of the protective helmet 1, that is to say when the membrane is inflated, the membrane 2 has a dimension corresponding in shape to that of the envelope 3, the membrane 2 then occupying a first volume corresponding to maximum volume of the envelope 3, the envelope 3 being designed to retain an expansion of the volume of the membrane 2 beyond the maximum volume of the envelope 3.

It will be understood that the membrane 2 is in accordance with the invention and it is designed to, in the unconstrained state, occupy a third volume greater than the maximum volume of the envelope 3.

The membrane 2 has a one-piece shape. Such a single-piece shape advantageously makes it possible to ensure that the active state of the protective helmet 1 is reached by pressurizing the membrane 2 by a single valve received in an orifice 31 of the membrane 2 provided for this purpose and in correspondence an opening 21 of the envelope.

For this, the membrane 2 is formed of a main strip 2a extending by junction strips 2b-2f spaced from each other. From a front end, the main band 2a extends through a first junction band 2b corresponds to a front band of the protective helmet 1, a second junction band 2c corresponds to a first top band, a third junction band 2d corresponds to a second top band, a fourth junction band 2e corresponds to a first rear band and a fifth junction band 2f corresponds to a second rear band.

The second junction strip 2c is of an inverted “Y” shape. The third junction strip 2d is "U" shaped.

The front, top and rear positions relate to the orientation of the protective helmet worn by the person.

It will be noted that in the front position of the protective helmet 1, the fourth junction band 2e is arranged between the first junction band 2b and the second junction band 2c.

It will also be noted that in the rear position of the protective helmet 1, the second junction strip 2b is arranged between the third junction band 2d and the fourth junction band 2e.

It will also be noted that in the rear position of the protective helmet 1, the first junction band 2b is arranged between the fourth junction band 2e and the fifth junction band 2f.

It has been found that the arrangement of the junction bands 2b-2e with respect to each other allows optimum protection of the person wearing the helmet in the event of impact. In Figure 3, there is shown a pattern of the casing 3 of the helmet formed by an assembly in two parts.

The references 2b-2f will be used to describe the shapes of the casing 2 in correspondence with the shapes of the junction strips 2a-2f.

As shown, a first part 3a for assembling the casing 3 is provided to be in correspondence with the first junction strip 2b and the second junction strip 2c. A second part 3b for assembling the casing 3 is provided to be in correspondence with the third junction strip 2d, the fourth junction band 2e and the fifth junction band 2f.

Each assembly part of the envelope 3 is advantageously sewn on its outline.

There is shown recesses 30 formed on the junction strips 2b-2f. These recesses 30 are preferably regularly formed to make it possible to optimize the evacuation of the air contained in the fabric.

These recesses 30 are dimensioned so that they allow the air to be evacuated when the membrane is inflated without however modifying the shape of the membrane.

In the active state of the protection device, markers 25 of the membrane 2 are visible through at least one recess 30 of the envelope in the active state of the protection device. These markers are an indicator of the active state of the protection device.

In Figure 4, there is shown a pattern of the membrane 2 forming the main strip 2a and the junction strips 2b-2f described above.

To assemble the protective helmet 1, it will be understood that the membrane 2 is first placed between two fibrous bands of the envelope 3 before sewing the envelope 3 in order to imprison the membrane 2.

A tensor 20 is provided to retain an unwanted expansion in volume of the membrane 2.

For this, a tensor 20 can be formed in a zone of the membrane 2 formed by the crossing of the main strip 2a with a junction band 2b-2e, here with the third junction band 2d.

The tensor 20 here takes on a solid “8” shape adapted to allow the expansion of the membrane zone 2 to be retained. Advantageously, in order to avoid damaging the membrane 2 during sewing, the latter is brought together in a smaller space by an element which loses this compacting function from the first inflation.

Advantageously, the pattern of the membrane is such that it makes it possible to have additional material allowing sewing or assembly at certain points with the casing 3, reducing the risk of damaging the sealed compartment of the membrane.

The fibrous envelope 3 is also formed by the assembly of two skins 3 ', 3 between which the membrane 2 is contained.

A first skin is intended to form an outer skin 3 ′ and a second skin is intended to form an interior skin 3 ″.

The inner skin 3 is that in contact with the head of the person to be protected, unlike the outer skin 3 '.

By way of example, the outer skin 3 'can be formed from a high resistance material such as Zilon fiber or Kevlar and the inner skin 3 "can be formed from a textile material such as polypropylene or else polyester and possibly comprising at least in part an elastane composition.

In this way, the outer skin 3 ′ provides protection against impacts for the wearer of the helmet, while the inner skin 3 ″ provides stable support for the wearer's head during an impact.

In FIGS. 5 to 7, various embodiments of a protective helmet according to the invention will be described. Only the shape of the membrane 2 will be described. Of course, the fibrous envelope 3 described above will be produced in a shape corresponding to the membrane 2.

In Figure 5, there is shown a first variant embodiment of the membrane 2, where it is also formed of a main strip 2a extending by junction strips 2b-2e spaced from one another. From a front end, the main band 2a extends through a first junction band 2b corresponds to a front linear band of the protective helmet 1, a second junction band 2c corresponds to a first top band, a third junction band 2d corresponds to a second top strip, and a fourth junction strip 2e corresponds to a first rear linear strip. The first junction band and the second junction band define between them a length of the membrane. The second junction band 2c and the third junction band 2d are advantageously of “Y” shape so as to ensure a better correspondence with the zones to be protected of the head of the helmet wearer. There is shown in Figure 5, two tensors, namely a first tensor 22 and a second tensor 23 formed on the membrane 2.

Each tensioner 22, 23 is provided to retain an unwanted expansion in volume of the membrane 2.

For this, each tensor 22, 23 can be formed in a zone of the membrane

2 formed by the crossing of the main strip 2a with a junction strip 2b-2e or even on another part of the main strip 2a.

In the example illustrated, the first tensor 22 and the second tensor 23 are formed in a junction zone between the main strip 2a and respectively the second junction strip 2b and the third junction strip 2c each in the shape of a Y.

It will be understood that such zones form surfaces for which the shape of the membrane 2 cannot be controlled when it is in its inflated state.

Each tensor 22, 23 is chosen in a shape adapted to the surface of the zone with which it is associated. Here the first tensor 22 is made in a rectangle shape while the second tensor 23 is made in a solid circle shape.

These tensors can be produced by plastic welding of a single layer of the membrane or alternatively of two opposite layers of the membrane.

In Figure 6, there is shown a second variant embodiment of the membrane 2, where it is also formed of a main strip 2a extends by junction strips 2b-2e spaced from one another. The main band 2a ends with a point 2a 'defining a front end of the protective helmet

In the plane shown, from the front end, the main strip 2a extends by four junction bands 2b-2e, namely successively a first 2b, a second 2c, a third 2d and a fourth junction bands 2e, each inclined with respect to the main strip 2a at an angle of between 10 ° and 90 °.

The second 2c and third 2d junction bands are of similar size, while the first junction band 2b is of shorter length than the second 2c and third 2d junction bands, preferably it is less than half, even more preferably it is less than two-thirds. The fourth junction band 2e is for its part less than half the length of the second 2c and third 2d junction bands.

The fourth junction strip 2e forms a rear strip of the protective helmet according to the invention.

Each tensor 24 is made in the shape of a solid circle. In Figure 7, there is shown a third variant embodiment of the membrane 2, where it is formed by a solid circular central strip 2a from which extend a plurality of peripheral strips 2b-2f.

The peripheral bands 2b-2f take a triangular shape so that the protection zone of the head of the wearer of the helmet extends in proportion to its distance from the central band 2a.

For each of these peripheral bands 2b-2f, a tensor 24 of shape similar to the peripheral band with which it is associated is formed.

It will be understood that the particular shape of the peripheral bands follows the patronage of a head whose areas to be protected have been identified.

In Figure 8, there is shown a ply 40 of multi-layered hygienic protection 41, 42, 43, 44 tear-off provided to be placed inside the helmet.

The layers 41, 42, 43, 44 forming the web 40 are advantageously glued together in a non-permanent manner. In other words, they can become detached from each other by successive tearing from one another.

For example, layers 41, 42, 43, 44 can be non-permanent self-adhesive. In other words, they are detachable from each other and re-glue to each other.

Any type of self-adhesive glue may be suitable.

Such a web 40 allows hygienic single-use use. Indeed, each layer 41, 42, 43, 44 can be torn successively after use of the helmet. In this way, it is ensured for the user to have a perfectly clean helmet for his head when using it.

In Figure 9, there is shown a damping structure 50 formed with the elastic membrane 2.

As shown, the damping structure 50 comprises a network of dampers 51, here represented by bubbles, connected to each other.

This network of dampers 51 is fluidly connected to the membrane (schematically represented), that is to say that it is formed at the same time as the membrane swells.

In Figure 10, there is shown a sealed connection system 60 for a valve comprising a lower part 61 and an upper part 62 provided for sealingly imprison the outline of an opening 63 formed in the membrane 2 and to ensure the tightness of a butyl valve 64.

The lower part 61 takes the form of a peripheral ring 61A comprising at its center a threaded opening 61B terminating in an internal shoulder 61C from which extends a hollow tube 61D.

The valve 64 comprises a lower portion 64A and an upper portion 64B separated by a shoulder 64C.

The upper part 62 also takes the form of a peripheral ring 62A from which extends at its center a connection sleeve 62B threaded on its periphery. Furthermore, a rigid tongue 62C, preferably made from one material with the peripheral ring 62A of the upper part 62, extends therefrom.

When mounting the connection system, the butyl valve 64 is inserted, by its lower portion 64A, into the hollow tube 61D of the lower part 61 to open out inside the membrane 2. The complementary shoulder 64C of the valve 64 then comes to bear against the shoulder 61C formed in the lower part 61.

The lower part 61 equipped with the valve 64 is designed to be inserted through the opening 63 under the elastic membrane 2, that is to say in the volume of the membrane in the active state for example.

Once the lower part 61 has been inserted under the membrane 2, the upper part 62 is brought together so that the upper portion 64B of the valve 64 penetrates the interior of the connection sleeve 62B. The shoulder 64C of the valve 64 then bears against the contour 62D of the end of the sleeve 62B. The rigid tongue 62C of the upper part of the sleeve 62B is then rotated so that the thread of the sleeve 62B of the upper part 62 penetrates the thread of the lower part 61 until it is fully tightened.

In the assembled state, the sealed connection between the membrane 2 and the sealed system 60 is provided by the surfaces of the rings 61A, 62A of the lower and upper parts 61, 62 and the sealed connection between the valve 64 and the sealed system 60 is provided by the surface of the shoulder 61C of the lower part 61 and the contour 62D of the end of the sleeve 62B.

In a particular application to this waterproof system 60, the membrane 2 used is a polyurethane film.

A sealing O-ring may be provided between the rings 61A, 62A of the lower and upper parts 61, 62. In Figure 11, there is shown a protective helmet 1 equipped with the waterproof connection system 60 and, moreover, a striker 70.

The striker 70 comprises a main body 71. From this main body 71 extends an outlet 72 of the striker 70 delimited by the latter by a recess 73. The outlet 72 of the striker 70 ends with a needle 74.

Furthermore, a radial stop 75 extends radially from the body 71 in order to ensure the locking in rotation of the firing pin 70 when a cartridge 76 is aimed there.

Of course, but if this is not shown, the body 71 of the striker 70 is provided to allow the screwing of a cartridge 76 and to pierce the cover of the cartridge 76 in order to release the gas contained therein through needle 72.

The operation of inflating the membrane 2 is carried out using the striker 70, the needle 74 of which is inserted into the valve 64 to reach the internal volume of the membrane 2.

The release of the striker 73 is then found resting on the upper part 62 of the sealed connection system 60. The cartridge 76 is then screwed into the body 71 of the firing pin 70. When mounting the cartridge, the firing pin 70 can be driven in rotation, its rotational travel can however be blocked by its radial stop 75 retained by a projection 62E provided on the upper part 62 of the sealed connection system 60.

The operation of deflating the membrane 2 is also carried out using the striker 70 not equipped with a cartridge 76, in order to release the gas contained in the membrane 2 into the atmosphere.

Advantageously, the screw pitch of the striker can be specific to the screw pitch of the cartridge.

The striker 70 can be linked to the helmet by a wire connection of the cord type for example.

In Figure 12, there is shown a pressure indicator 80 formed by a rigid hollow tube 81 or semi-rigid linked to the membrane 2 and fluidly connected to the volume of the membrane 2 by an opening 82, the tube 81 comprising a compressible element 83, here a spring, pushing a gauge 84 forming a pressure indicator. The hollow tube 81 is made of a transparent material to make the position of the gauge readable.

The hollow tube 81 can be bonded to the membrane 2 by heat sealing or by welding, for example. As shown, the hollow tube 81 can be positioned perpendicular to the wall of the membrane 2 to which it is attached, or alternatively be positioned along the latter.

When the membrane is pressurized, the pressure in the membrane 2 penetrates the opening 82 to reach the volume of the tube 81 and then pushes the gauge 84. The displacement of the gauge 84 is then representative of the pressure level in membrane 2.

The tube 81 and the compressible element 83 are advantageously sized so that a first extreme position of the gauge corresponds to the inactive state of the protection device 1 and a second extreme position of the gauge corresponds to the active state of the monitoring device. protection 1.

The characteristics described in relation to the protective helmet apply of course to the protective device and vice versa.

Obviously, the invention is not limited to the examples which have just been described and numerous modifications can be made to these examples without departing from the scope of the invention. In particular, the different characteristics, forms, variants and embodiments of the invention can be associated with each other in various combinations insofar as they are not incompatible or mutually exclusive. In particular, all the variants and embodiments described above can be combined with one another.

Claims

1. Protection device (1) of an object or a person, the protection device (1) comprising a waterproof elastic membrane (2) provided to receive a gas and a fibrous envelope (3) containing said membrane (2) ):

in the resting state of the protection device (1), the membrane (2) has a dimension different from that of the envelope (3) and the envelope (3) containing the membrane (2) can be folded,

in the active state of the protection device (1), the membrane (2) has a dimension corresponding in shape to that of the casing (3), the membrane (2) then occupying a first volume corresponding to the maximum volume of the envelope (3), said second volume, the envelope (3) being provided to retain an expansion of the volume of the membrane (2) beyond the maximum volume of the envelope (3), said envelope (3) being designed to take a shape conforming to the object or person to be protected, and in that, in the unconstrained state, the inflated membrane (2) can occupy a third volume greater than the maximum volume of the envelope (3).

2. Protective device (1) according to the preceding claim, characterized in that, in the rest state of the protective device (1), the membrane (2) is of distinct shape from the casing (3).

3. Protective device (1) according to any one of the preceding claims, characterized in that it comprises at least one valve (20).

4. A protective device (1) according to any one of the preceding claims, characterized in that the envelope (3) and / or the membrane (2) comprises a marker (25, 30) corresponding to the state of rest of the protective device (1), to an indicator of a deflated state of the membrane (2) and, in the active state of the protective device (1), to an indicator of an inflated state of the membrane ( 2) to occupy said first volume.

5. Protective device (1) according to any one of the preceding claims, characterized in that the pressure of the membrane (2) is between 1 bar and 30 bars, preferably the pressure is between 2 bars and 6 bars.

6. Protective device (1) according to any one of the preceding claims, characterized in that the casing (3) comprises folds allowing folding and unfolding repeatable each time the protection device (1) is used.

7. Protective device (1) according to any one of the preceding claims, characterized in that the membrane comprises at least one tensor (22, 23, 24) making it possible to control the expansion of the membrane in order to obtain the desired shape.

8. Protective helmet for a person, characterized in that it is formed by a protective device (1) according to any one of the preceding claims, and in that the fibrous envelope (3) is adapted to take the shape of the protective helmet when the protective device (1) changes from its rest state to its active state.

9. Protective helmet according to the preceding claim, characterized in that the protective helmet comprises an adjustment system for adapting the protective helmet to the person wearing it.

10. A method of assembling a protection device (1) for an object or a person according to any one of the preceding claims, characterized in that it comprises the following steps consisting of:

a patronage step in which a material forming the fibrous envelope or the waterproof membrane is positioned on an object or the part of the body to be protected in order to determine the protection zones, then these protection zones are projected onto the material to create a two-dimensional plane of the fibrous envelope or the waterproof membrane;

a step of assembly by welding of this membrane (2);

- a step of including a valve of the membrane (2);

a verification step consisting in measuring an expansion of the volume of the membrane (2) beyond the maximum volume of the envelope (3).