EP2395865A1

EP2395865A1 - Deformable safety helmet

Info

Publication number: EP2395865A1
Application number: EP10707090A
Authority: EP
Inventors: Rémi FINIEL; Shaw Kaake; Ku Cheng-Huei; Xiang Zl Ping; Roger Davis
Original assignee: KUJI SPORTS Ltd
Current assignee: KUJI SPORTS Ltd
Priority date: 2009-02-13
Filing date: 2010-02-11
Publication date: 2011-12-21
Anticipated expiration: 2030-02-11
Also published as: EP2395865B1; WO2010092254A1; US20120047635A1; JP2012518097A; JP5693472B2; CA2752516C; US8850622B2; FR2942111A1; FR2942111B1; CA2752516A1; DK2395865T3

Abstract

The invention relates to a safety helmet (10) comprising damping elements (13), for example made from expanded polystyrene, added to a shell (12) made from an elastically deformable material. All of the shell (12)-facing surface of the damping elements (13) which are arranged along the periphery of the opening (11) is positioned against the shell (12) so as to form an inner supporting belt completely in contact with the shell (12). The helmet (10) is arranged such that, once the head is in position in the helmet cavity, the supporting belt deforms by means of the elastic deformation of the shell (12) according to the morphology of the head, permanently tightening the supporting belt against the head in a substantially uniform manner along the length of the supporting belt.

Description

Deformable protective helmet

Technical field of the invention

The invention relates to a protective helmet defining an open cavity on the outside through an opening for the engagement of the head in the cavity, comprising an outer shell in one piece, a plurality of elements dampers reported inside the shell, and connecting means for connecting the damping elements to each other.

State of the art

A protective helmet of this type is known from US6665884B1, which provides a rigid shell that deforms only under the effect of an external impact. Side, front and top damping elements are attached to the inside of the hull. Each of the lateral damping elements is subdivided into a lateral part fixed to the shell and a rear part freely articulated to the lateral part. Each side damper element is therefore partially attached to the hull. The free ends of the rear parts are interconnected by an elastic band. The rear parts and the elastic band are located at a distance from the inner face of the shell. This results in the presence of dead volumes interposed between the shell and the damping elements, which is not an optimal protection. The front damping element is completely dissociated from the lateral damping elements, with the interposition of empty intervals at which no clamping is applied to the head in position in the helmet cavity. The tightening of the head is realized only laterally and from behind, which implies a questionable helmet and protection. Finally, the clamping function is performed by the rear elastic band and the compressibility of the lateral damping elements. The hull located at a distance from these bodies with interposition of dead volumes as indicated above does not participate in tightening the head and has no possible adaptation to the morphology of the head of the user. Only the lateral elements adapt to the morphology of the head.

In addition, shocks on a helmet during a fall are rarely purely perpendicular to the hull and it often happens that a tangential component to the hull generates a violent torque on the head and then on the neck. These sudden rotations of the head cause internal lesions on the connecting elements of the brain to the cranial box. The helmets of the prior art do not protect this phenomenon, and are not completely satisfactory on the issue of safety.

Object of the invention

The object of the invention is to provide a protective helmet for optimizing comfort, hold, aesthetics and safety regardless of the morphology of the head of the user of the helmet.

The goal is achieved by a helmet according to the appended claims, in particular by the fact that the damping elements are constituted by a rigid foam material, the shell is made of an elastically deformable material, and that the face turned towards the the shell of the damping elements disposed at the periphery of the opening is integrally attached against the inner face of the shell to form an inner support belt completely in contact with the shell, the helmet being arranged so that a position of the head in the cavity causes a deformation of the support belt by elastic deformation of the shell in according to the morphology of the head, generating a permanent tightening of the support belt against the substantially uniform head along the support belt.

The damping elements arranged at the periphery of the opening are for example positioned side by side so as to form a support belt bordering the entire periphery of the opening in order to avoid empty intervals along the periphery of the opening. the opening. As the side facing the shell damping elements periphery of the opening is integrally reported against the shell, it results in the absence of dead volumes interposed between the shell and the damping elements, giving optimum protection. The shell is designed to elastically deform in flexion when the head is in position in the helmet cavity to generate, by elastic return of the shell to its natural configuration before placing the head in the cavity, tightening the belt support against the head. The shell therefore adapts automatically to the morphology of the user's head. All damping elements bordering the periphery of the opening participate in the clamping and adapt to the morphology of the head. A support belt thus formed and arranged so as to deform when the head is in position in the helmet cavity, by deformation of the shell against which it is completely attached, has the effect of tightening the head permanently and uniformly around the waist, which implies improved helmet wear and protection.

Brief description of the drawings

Other advantages and features will emerge more clearly from the following description of particular embodiments of the invention given by way of non-limiting example and represented in the accompanying drawings, in which: FIG. 1 is a bottom perspective view of a helmet according to the invention, FIG. 2 is a longitudinal sectional view of the helmet of FIG. 1, FIGS. 3 to 6 illustrate different variants of connection means between the elements. shock absorbers, Figures 7 to 10 show different shape variants of the damping elements, Figure 11 is a sectional view of a helmet comprising spacer elements.

Description of the Preferred Modes of the Invention

The protective helmet 10 of Figures 1 and 2 defines a cavity open on the outside through an opening 11 for the engagement of the head within the cavity. The helmet 10 has an outer shell 12 in one piece and devoid of nicks. A plurality of damping elements 13 is attached to the inside of the shell 12 so as to constitute a damping cap covering substantially all of the inner face of the shell 12. Connecting means may be provided to connect the elements dampers 13 between them, but such connecting means are not essential. It is possible to provide that each damping element 13 is attached to the shell without connection with the other damping elements 13.

It should be understood by "notch" a local elongated removal of material over the entire thickness of the helmet (that is to say over the entire thickness of the calotin and over the entire thickness of the shell) arranged so to debouch on the edges of the helmet. However, the shell 12 may include local ventilation holes having a closed contour, that is to say, not leading to the edges of the helmet. The damping elements 13 are constituted by expanded polystyrene (EPS) or any other substantially rigid foam which has an economic interest comparable to that of the EPS or interesting damping properties. The shell 12, for its part, is made of an elastically deformable material, such as a thermoplastic polymer material, such as polycarbonate, acrylonitrile butadiene styrene (or ABS), polystyrene, glycolized polyethylene terephthalate (or PETG). ), polyvinyl chloride (or PVC). The choice of the material of the shell 12 is such that the shell 12 has a satisfactory resistance to external shocks and that the bending modulus of the material is between 1500 and 4500 MPa. For a resilient deformation capacity in desired bending, the thickness of the outer shell 12 is for example between 0.5 and 3 mm, depending in particular on the modulus of elasticity. The material constituting the shell 12 also has a tensile elongation at break characteristic which is preferably greater than 10%.

When used, the connecting means between the damping elements 13 can be made in any way, and are for example designed to allow relative movements between the damping elements 13.

A first solution consists in using a single structure 14 connecting all the damping elements 13 to each other. In the case where the cushioning cap consists of an upper damping element around which is distributed angularly a plurality of lateral damping elements, front and rear, the single structure 14 may for example take the form of a spider whose head is attached to the upper damping element and each leg ensures the connection between the upper damping element and a peripheral damping element. In FIG. 3, the top, lateral, front and rear damping elements come from overmolding on the single structure 14. On the other hand, in FIG. single 14 is not overmoulded, but it is trapped between the damping elements 13 and the inner face of the outer shell 12.

Another solution is to use a plurality of discrete connection members individually performing a local connection between two damping elements 13. In the case where the damping cap is constituted by a top damping element around which are angularly distributed a plurality of side damping elements, front and rear, each connecting member provides the connection between the upper damping element and a peripheral damping element. In FIG. 4, each connection member takes the form of a loop 15 formed by the closure on itself of a textile tape or Velcro® type self-gripping material. One end of the loop 15 passes through a through hole in the top damping member, and the opposite end passes through a through hole of the bonded peripheral damping member. In FIG. 6, on the other hand, each connecting member is formed by an insert 16 in two axially offset parts. Each part is intended to cooperate with either the upper damping element or with a peripheral damping element, and for this purpose comprises a plurality of fir-tree-shaped return tabs.

The side facing the shell 12 of the damping elements 13 disposed at the periphery of the opening 11 is integrally attached against the inner face of the shell 12 to form an inner support belt bordering the periphery of the opening and completely in contact with the hull. The face facing the shell 12 of each damper element 13 constituting the support belt is fully in contact with the inner face of the shell 12 when the head of the user is in position in the cavity of the helmet. To form a support belt bordering the entire periphery of the opening 11 to avoid empty intervals along the periphery of the opening 11, the damping elements 13 arranged at the periphery of the opening 11 can be positioned side by side or placed at a negligible distance of the order of a few millimeters. The support belt has a ring shape internally defining the contour of the opening 11. Externally, the support belt is completely in contact with the inner face of the shell 12, ensuring the absence of interposed dead volumes between the shell 12 and damping elements 13 constituting the belt to provide optimum protection.

The shape, the dimensions and the thickness of the shell 12, the thickness of the damping elements 13 constituting the support belt, are chosen so that the internal dimensions of the support belt (delimiting the periphery of the opening 11) are perfectly adjusted to the expected perimeter of the head in the intended contact area of the head. The helmet is thus arranged so that a positioning of the head in the helmet cavity causes a deformation of the support belt resulting from an elastic deformation in flexion of the shell, generating by elastic return of the shell towards its configuration natural (before positioning the head in the helmet cavity) a permanent tightening of the support belt against the substantially uniform head along the support belt.

Whatever the connecting means between the damping elements 13, the attachment of the damping cap on the inner face of the shell 12 can be practiced by fixing the shell at least one damping element 13 of the calotin. Such fastening means may be designed to allow a slight sliding between the shell 12 and the damping elements 13 fixed. These slight glides between the damping elements 13 and the shell 12, as well as the movements between the damping elements 13, can generate potentially unpleasant noises against which it is possible to act by covering the inner face of the shell and / or the elements finishers of a felt-type coating, spray, silicone ... In the case where the cushioning cap consists of an upper damping element around which is distributed angularly a plurality of lateral damping elements, front and rear, a first solution is to use fastening means ensuring a solidarization of the upper element with the inner face of the shell 12. In a second solution, the helmet 10 comprises means for integrally attaching to the shell 12 the constituent damping elements of the support belt so that the support belt is completely secured. of the inner face of the shell 12. It should then be provided, preferably, that the means for integrally attaching to the shell 12 the constituent damping elements of the support belt allow a slight sliding between the shell 12 and the damping elements set. This characteristic can be obtained by using hook-and-loop fastening means of the Velcro® type or of the cooperating loop / hook type, and has the advantage of a better adaptation of the damping elements to the morphology of the head.

In a variant improving the comfort at the contact between the support belt and the head, compressible elements 17 may be arranged on the face opposite to the face fixed to the shell 12 of the constituent damping elements of the support belt. Such compressible elements 17 may cover all or part of the periphery of the support belt, and are made by a flexible and resilient foam, for example ethylene vinyl acetate (EVA), reported or provided during the manufacture of the damping elements of the support belt. Such compressible elements 17 have the function of creating a complementary belt which makes it possible to position inside a helmet provided for a given head perimeter, a head having an upper perimeter by deformation of the compressible elements 17. In addition, filling elements may be arranged to fill the interstices between the damping elements 13, on all or part of the damping cap. Such filling elements may be made of any flexible and resilient material adapted, for example ethylene vinyl acetate (EVA).

According to one embodiment which is in no way limiting, the filler elements arranged between the damping elements 13 may be constituted by spacer elements 18. As illustrated in FIG. 11, such spacer elements 18 may be constituted by elastic connectors adopting a general shape of V which aim to maintain permanently a minimum space at rest between each of the damping elements 13. By deformation of the elastic connectors under the effect of external forces, this minimum space can decrease temporarily, until returning to, its natural dimension by elastic return of the connectors to their natural resting configuration when external forces cease. This embodiment is particularly advantageous in the absence of the compressible elements 17.

In addition to the creation of a sliding between the shell 12 and the damping elements 13, the spacer elements 18 have a first advantage of ensuring the constant maintenance of a plating effect of the damping elements 13 against the inner face of the shell 12, eliminating any mobility of the elements 13 especially as the helmet is not used. They also make it easier to deform the assembly formed by the shell and the segmented bonnet by promoting sliding. Finally, they make it possible to eliminate the noises and creations induced by the contact between the elements 13 with each other and with respect to the shell 12. The spacer elements 18 may be obtained by thermoforming or by injecting material (for example PE or PP). The helmet 10 may further comprise a chinstrap connected at its ends to two opposing damping elements each belonging to the support belt.

Figures 7 to 10 are intended to illustrate the different shape variants that can take the damping elements 13 of the damping hood. In FIG. 10, an upper damping element is connected to a plurality of lateral damping elements, front and rear, arranged at the periphery of the summit element. Figure 9 is a variant of Figure 10, wherein the peripheral damping elements are subdivided into two independent elements offset towards the bottom of the cavity. On the other hand, FIGS. 7 and 8 show with a distribution density respectively large and smaller, a cap where the damping elements 13 are hexagonal and distributed uniformly over the entire internal face of the shell 12.

The set of helmet variants described above have the advantage of a high quality of ventilation inside the helmet. Indeed, the heat emanating from the head of the user is mainly radiation on the circumference of the skull. Slits or interstices between the elements 13 create an air circulation network that allows efficient removal of heat and moisture. This effect can be enhanced if the shell 12 is provided with holes opening outwards and facilitating the creation of a variable ventilation air flow depending on the mobility of the user.

Finally, with regard to safety, the previously described embodiments in which the lateral damping elements 13 are floating make it possible to absorb a portion of the energy by sliding and pivoting between the head and the shell in the case of tangential components of forces. This displacement of a few tens of millimeters is essential to allow to dampen the stress peak and stay below the threshold of lesions of the brain. In the case a greater effort, a sliding in the plane of the support belt, between the head and the helmet is possible to damp the shock wave. This possibility is allowed thanks to the free deformation of the perimeter of the support belt.

In an advantageous variant, the attachment means of the upper damping element 13 and the shell 12 may serve as a fuse and allow at least partial separation of the two elements, allowing a greater rotation of the shell relative to the cap, making the almost zero effort transmission. Such a fixing means can be made with glue, for example of the "hot melt glue" type, or a magnet or Velcro® type self-gripping material. The hull 12 can not be detached because the jugular or equivalent under the chin of the user guarantees the unity of the assembly.

Claims

claims

1. Protective helmet (10) delimiting a cavity open to the outside through an opening (11) for engagement of the head in the cavity, comprising an outer shell (12) in one piece, a a plurality of damping elements (13) attached to the inside of the shell (12), characterized in that the damping elements (13) consist of a rigid foam, the shell (12) is made of an elastically deformable material, and in that the side facing the shell (12) of the damping elements (13) disposed at the periphery of the opening (11) is integrally attached against the inner face of the shell (12) to form an inner belt of support completely in contact with the shell (12), the helmet (10) being arranged so that a position of the head in the cavity causes a deformation of the support belt by elastic deformation of the shell (12) in function of the morphology of the head, generating a permanent tightening of the support belt against the substantially uniform head along the support belt.

2. Helmet according to claim 1, characterized in that it comprises means for integrally attaching to the shell (12) damping elements (13) constituting the support belt.

3. Helmet according to claim 2, characterized in that the means for integrally fixing the shell (12) damping elements (13) constituting the support belt allow a slight sliding between the shell (12) and damping elements (13) fixed.

4. Helmet according to one of claims 1 to 3, characterized in that the material of the outer shell (12) has a flexural modulus of between 1500 and 4500 MPa.

5. Helmet according to one of claims 1 to 4, characterized in that the thickness of the outer shell (12) is between 0.5 and 3 mm.

6. Helmet according to one of claims 1 to 5, characterized in that compressible elements (17) are arranged on the face opposite to the face attached to the shell (12) of the damping elements (13) constituting the belt d 'support.

7. Helmet according to one of claims 1 to 6, characterized in that it comprises connecting means (14 to 16) for connecting the damping elements (13) together.

8. Helmet according to claim 7, characterized in that the connecting means (14 to 16) allow relative movements between the damping elements (13).

9. Helmet according to one of claims 7 and 8, characterized in that the connecting means (14 to 16) comprise a single structure (14) connecting all the damping elements (13) between them.

10. Helmet according to one of claims 7 and 8, characterized in that the connecting means (14 to 16) comprise a plurality of discrete connection members (15, 16) individually performing a local connection between two damping elements ( 13).