IT202100014561A1 - PROTECTIVE HELMET WITH VISOR WITH LC LAYER RECESSED INTO THE STRUCTURAL LENS - Google Patents

Description

DESCRIPTION

The object of the present invention is a protective helmet for the practice of activities sports and/or the use of motorized vehicles, equipped with a visor for the eyes. Protective helmets often include an eye shield. In some cases this visor has the sole purpose of protecting the user?s eyes against the entry of splinters, dust or simply against the wind. In other cases, however, the visor also provides protection against excessive light.

Generally protection from light ? obtained simply through the use of pigments which lead the visor to transmit only a fraction of the incident light. Filters of this type are generally classified into categories (S0, S1, S2 etc?) with increasing absorption levels. However in many situations the user needs? to have a level of light filtering that varies according to the different luminosity? external, as for example in the case of a motorcyclist who, from a sunny area, crosses a tunnel.

Technologies are known that seek an answer to this problem. However, these known technologies have limitations which actually make them ineffective.

Photochromic lenses are known, made with treatments or materials which react to sunlight causing the lens to darken. However, these known lenses are all too slow to react to changes in brightness. very quick. Furthermore, the optimal substrate on which to carry out these treatments? glass, what? a material that is hardly compatible with protective devices.

Are electrochromic lenses known which typically use polymers capable of modifying the properties of the lenses? optics when a magnetic field is applied. These lenses, albeit pi? faster than photochromic lenses, they are still quite slow. Furthermore, the high power required to obtain the change of state limits the maximum number of possible changes, making this type of lens functional for automatic adaptation to ambient light only in the presence of bulky batteries.

Finally, lenses are known which use layers of liquid crystals, and are the only ones capable of reacting quickly to changes in ambient light. However lenses of this type are still substantially unused given the persistence of a series of problems, including: low brightness? filter maximum, presence of unwanted polarizations, interference with other transparent elements, unwanted reactions to mechanical stress. For these reasons, these lenses find application only in the field of welding protection devices, in which TN (twisted nematic) type planar liquid crystal LC screens are widely used. However, these screens are not suitable for protection from sunlight under normal conditions, being in fact too dark in their state of maximum transmission and having a very small field of vision. Also known are techniques for applying devices which use liquid crystals of the GH (Guest Host) type. This type of liquid crystal does not use polarizing filters and pu? therefore achieve transparency much greater than 50%, thus resulting potentially more? suitable for use in sun protection devices under normal conditions. However, even this type of lens presents a number of problems. In fact, GH-type liquid crystal LC filters react to mechanical tensions, creating inhomogeneities? unwanted in the level of transparency. Most of the existing helmet visors ? made in such a way that, when a GH-type LC layer is applied, the latter undergoes deformations and mechanical stress such as to compromise its uniformity of transparency. Furthermore, helmet visors are typically made with the injection molding technique which generates parts with residual internal tensions that interfere with the liquid crystals, creating a birefringence effect typically called ?rainbow? which makes viewing uncomfortable.

Purpose of the present invention? that of solving the problems encountered in the state of the art in order to obtain a helmet equipped with a visor with variable transparency that is truly effective and comfortable to use.

That purpose? achieved by a protective helmet according to claim 1. The dependent claims identify further advantageous embodiments of the invention.

The characteristics and advantages of the protective helmet according to the present invention will be evident from the following description, given by way of non-limiting example, in accordance with the attached tables, in which:

- figure 1 shows a side view of a protective helmet according to the present invention, in an embodiment;

- figure 2 shows a side view of a protective helmet according to the present invention, in a further embodiment;

- figure 3 shows a cross-sectional view of the protective helmet according to the present invention; - figure 4 shows a detail of the visor of the helmet of figure 3;

- figure 5 shows an exploded diagram of the structure of the lens unit of the visor of the safety helmet, in an embodiment.

With reference to the attached figures, with 1 yes ? overall indicated a protective helmet for the practice of activities? sports or for the use of motorized vehicles, equipped with a visor for the eyes, in accordance with the present invention.

The helmet 1 comprises a shell 2, to protect at least one part of the user?s head, to which ? a visor unit 3 is engaged, to protect the user?s eyes.

As shown in figure 3, the shell 2 comprises a rigid outer shell 21, for example in plastic or composite material, and a collapsible inner shell 22, for example in expanded polyurethane or expanded polystyrene.

The inner shell 22 ? covered, on the side intended to come into contact with the user?s head, with padding, mainly made of fabric, designed to improve comfort when using the helmet. Preferably, shell 2 ? equipped with a communication system. For example, helmet 1 includes a bone conduction sound system.

Preferably, the shell 2 pu? also include additional components typical of a helmet, such as air vents, spoilers, aerodynamic appendages, signal lights, communication systems, displays.

The cap 2 ? provided with a front opening 23 in correspondence with the user's eye region, intended to be closed by the visor unit 3 at least during use of the helmet 1. Said opening? characterized by a closed perimeter in the case of a full-face helmet (as in figure 1), while it is configured as a recess in the perimeter of the shell in the case of helmets without a chin guard (as in figure 2).

The cap 2 ? equipped, on both sides, with a seat arranged near the user's ear region, able to house a relative anchor pin 32 of the visor unit 3 so that the latter is pivoted to the cap 2 to open and/or or close the opening 23.

In an embodiment, the visor group 3 ? fixed to the shell 2.

In a further embodiment, the visor unit 3 ? removable from the shell 2, for example to be replaced with a different visor assembly to adapt the helmet 1 to specific light situations.

The visor unit 3 comprises a variable transparency lens unit 4 that is truly effective and comfortable to use.

As can be seen in the example of figure 5, the lens group 4 comprises a structural lens 41 or external lens. In one embodiment, the lens group 4, and in particular the structural lens 41, is directly fixed to the shell 2.

The structural lens 41 ? at least partially transparent. This lens can be made with transparent materials and without the addition of pigments, reaching a light transmission close to 100%. Or can? be made using materials or combinations of pigments, materials and surface treatments in order to filter a part of the non-visible light or radiation, possibly even in a non-uniform way over the spectrum to obtain optimal vision in different environmental conditions.

Preferably the structural lens 41 ? made of plastic material, for example polycarbonate or polyamide.

In an embodiment intended for use in specific light conditions, the structural lens 41 ? pigmented so as to modulate the absorption spectrum, in particular in this case the structural lens 41 can? also be pigmented in order to modulate the contrast in specific light situations, for example by increasing it.

The structural lens 41 has an external surface 411 and an internal surface 412.

As seen in FIGS. 3 and 4, the structural lens 41 has a greater thickness near the lens. of at least part of the perimeter. The thickened area of the structural lens 41 makes it possible to define a rear recess, i.e. a recessed inner surface 412, preferably of a cylindrical shape.

Preferably, the outer surface 411 of the structural lens 41 is treated with a coating, for example anti-scratch, and/or mirror, and/or anti-reflection, and/or multilayer.

The lens group 4 comprises a liquid crystal film 43 (hereinafter LC film), provided with an external face 431, facing the structural lens 41, and an internal face 432.

The film LC 43 ? of the GH (Guest-Host) type liquid crystal type. In this type of LC film dichroic pigments are dispersed in a liquid crystal matrix, the magnetic field drives the orientation of the liquid crystals which, in turn, drives the orientation of the pigments. Typically in the ?active? the crystals take on a helical configuration and the pigments arrange themselves on planes parallel to the surface of the film, while in the ?deactivated? crystals and pigments are arranged perpendicular to the film surface. Preferably, the LC 43 film has a transparency to visible light of at least 60% in its brightest state. clear and at most 40% in its state pi? dark. For example, the LC layer pu? have a transparency of about 30% in its dark state and about 70% in its darkest state. clear.

In an embodiment, shown for example in figure 1, the structural lens 41 has a cylindrical curvature, ie it is curved on a single axis. Advantageously, this shape allows the LC layer 43 to be laminated to the structural lens 41 in an optimal manner.

The film LC 43 ? controlled by an electronic board 5, described below, which produces a signal whose intensity? increases as the ambient light increases.

Preferably, the film LC 43 ? assembled behind the structural lens 41, in particular the external face 431 of the LC layer 43 ? laminated to the recessed inner surface 412 of the structural lens 41, as shown in Figure 5.

The different films are preferably assembled using OCA (optically clear adhesive) double-sided adhesive film. Advantageously, this configuration protects the LC film 43 from contact with any sealing gaskets 49 and creates a structural perimeter rib 415, as seen in figure 4.

In an embodiment, shown in figures 3 and 4, the shape of the film LC 43 ? contained in the shape of the structural lens 41. Therefore, the shape portion of the structural lens 41 not occupied by the shape of the LC film 43 defines a free edge 413. Preferably, on at least a portion of said free edge 413 of the structural lens 41? a covering layer 414 is arranged. As a result, around at least a part of the perimeter of the LC film 43? there is a covering layer 414 applied to the structural lens 41. Preferably, internally to the LC film 43, i.e. on the side of the internal face 432, anti-fog and/or anti-reflection treatments can be applied or a real further layer equipped with a anti-fog and/or anti-reflection.

In an embodiment shown in figure 5, the lens group 4 comprises a depolarizing film 42 arranged externally to the LC film 43, ie in correspondence with the external face 431. The depolarizing film 42 is? then arranged between the structural lens 41 and the LC film 43.

The depolarizing film advantageously eliminates interference between the LC layer 43 and the internal tensions present in the structural lens 41 and makes vision comfortable and uniform.

The depolarizing effect? obtained preferably by means of a birefringent film characterized by a wave phase shift between the two optical axes greater than 1500nm.

The visor unit 3 comprises an electronic board 5 suitable for controlling the LC film 43. The electronic board 5 comprises a photovoltaic cell and an electronic circuit powered by the photovoltaic cell. In one embodiment, the electronic card 5 comprises a single photovoltaic cell, arranged in a frontal and central area, and two integrated circuits positioned at the rear, laterally, on one side and on the other with respect to the photovoltaic cell. Preferably the photovoltaic cell operates at the same time as a sensor of the quantity? of light in the environment and as feeding of the LC film; in fact, major ? the quantity? of light that invests the photovoltaic cell, pi? high ? the power generated by the photovoltaic cell, pi? high ? consequently the power with which the film LC ? powered and more this LC lens darkens.

Preferably, the response curve between the input signal and the output signal from the electronic board 5 is modifiable according to the needs of the user.

Advantageously, the photovoltaic cell is located close to the structural lens 41, thus receiving more light. In particular, the electronic board 5 with the photovoltaic cell ? placed behind the structural lens 41, and the photovoltaic cell ? facing the structural lens 41.

Preferably, the structural lens 41 ? equipped with a multilayer mirror treatment.

Preferably, the electronic board 5 ? assembled internally to the structural lens 41, for example by interlocking or by means of double-sided adhesive film and protected at the rear by a shell 31.

Advantageously, the photovoltaic cell receives light filtered by the structural lens and therefore reacts to the same component of the ambient light that the user?s eye receives, net of the intervention of the LC film.

Preferably the electronic board 5 ? arranged outside the perimeter defined by the front opening 23 of the cap 2, so that, with the visor 3 lowered, the electronic card 5 is outside the perimeter of the opening 23 and does not lead to a significant reduction in the user's field of vision . Advantageously therefore, the photovoltaic cell ? positioned in such a way as to be in an area of the field of vision of the user already? occluded by shell 2 of helmet 1.

In one embodiment, the space 33 created between the structural lens 41 and the protective body 31 is sealed or sealed and protects the electronic card 5, said card can? be protected, alternatively or additionally, by protective coatings or embedded in resins.

In one embodiment, the helmet 1 includes a battery capable of supplying more? power to the electronic board 5; eventually this battery can? also be used to power other electronic devices such as traditional or bone conduction audio systems, intercoms, ?head-up? or traditional, signal lights, emergency call systems, cameras or sensors.

Preferably the cap 2 comprises a photovoltaic plate positioned at least partially outside the outer shell 21. Preferably, the photovoltaic plate is? a flexible plate deformed to follow the curvature of the cap 2. Preferably, the photovoltaic plate? connected to the battery.

In summary therefore, the protective helmet 1 for sporting practice or for the use of motorized means in accordance with the present invention comprises:

- a protective cap 2 which, with the helmet on, protects at least part of the user's skull; - an at least partially transparent structural lens 41;

- a GH-type LC film 43 positioned inside the structural lens 41;

- in which the structural lens 41 ? provided with a recessed internal surface 412 in which ? placed the film LC 43.

Advantageously, this configuration avoids contact between the LC film 43 and the sealing gaskets 49 of the opening 23 and at the same time creates a structural perimeter rib 415.

Furthermore, the area of the visual field outside the film LC ? obstructed by a covering layer 414 applied to the structural lens 41. Advantageously, the covering layer allows the recessed configuration of the lens to be adopted without this? involves infiltrations of unfiltered light from the LC layer 43 at the free edge 413.

Advantageously, the protective helmet 1 for sports practice or for the use of motorized means in accordance with the present invention ? equipped with a truly effective and comfortable variable transparency visor in use.

? it is clear that a person skilled in the art, in order to satisfy contingent needs, could make modifications to the device described above, all contained within the scope of protection as defined by the following claims.

Claims (11)

1. Protective helmet (1) for the practice of outdoor activities sports or for the use of motorized vehicles, comprising a shell (2) equipped with a front opening (23), in correspondence with the user's eye region, closed by a visor unit (3), characterized in that said visor group (3) includes: - at least one at least partially transparent structural lens (41), provided with an internal surface (412); - a liquid crystal LC film (43) of the Guest-Host type suitable for modifying its own level of transparency, arranged behind the structural lens (41); - at least one electric source for feeding the LC film (43); - in which the structural lens (41) ? provided with a recessed inner surface (412) in which ? housed the film LC (43). 2. Protective helmet (1) according to claim 1, wherein said LC film (43) has a transparency to visible light of at least 60% in its brightest state. clear and at most 40% in its state pi? dark. 3. Protective helmet (1) according to claim 1 or 2, wherein said electric source for feeding the LC film (43) is? connected to an electronic board (5) which controls the LC film (43) and which produces a signal whose intensity? increases as the ambient light increases. 4. Protective helmet (1) in accordance with claim 3, wherein the electronic card (5) is equipped with a response curve, between an input signal and an output signal, which ? modifiable according to the needs of the user. 5. Protective helmet (1) in accordance with claim 3 or 4, wherein said electronic board (5) ? arranged outside a perimeter defined by the opening (23) of the cap (2) so as not to obstruct the user?s field of vision. 6. Protective helmet in accordance with any one of the preceding claims, wherein said structural lens (41) is equipped with a multilayer mirror treatment. 7. Protective helmet according to any one of the preceding claims, in which both the structural lens (41) and the LC film (43) have their own shape, and in which the shape of the LC film (43) is? contained within the shape of the structural lens (41), and in which a free edge (413) of the structural lens (41) not covered by the LC film (43) is covered at least partially by a covering layer (414). 8. Protective helmet (1) in accordance with any one of the preceding claims, wherein the visor unit (3) comprises at least one depolarizing layer (42) arranged between the structural lens (41) and the LC film (43). 9. Protective helmet (1) according to any one of claims 1 to 7, wherein the structural lens (41) is? a thermoformed plate in polymeric material. 10. Protective helmet (1) in accordance with any one of the preceding claims, wherein said cap (2) comprises: - a rigid outer shell (21) and a collapsible inner shell (22); - a photovoltaic plate positioned at least partially outside the outer shell (21), said plate being connected directly to the electric source for feeding the LC film (43), or through the interposition of a battery. 11. Protective helmet (1) in accordance with any one of the preceding claims, wherein said cap (2) comprises: - a rigid outer shell (21) and a collapsible inner shell (22), - a bone conduction audio system.