EP2939556A1 - Helmet adapted to its use constraints - Google Patents

Abstract

The invention relates to a helmet for sporting practice (1).

The helmet includes an outer shell (2) for positioning on a skull, the outer shell including:
an upper part (21) intended to cover at least the summit part (211) of the skull, the material forming the upper part having suitable mechanical properties so that the upper part satisfies a homologation standard defined for the intended use of the skull; helmet ; and
- a lower portion (22) integral with the upper part so as to form a single piece, the lower portion extending continuously to cover at least partially, the lateral and posterior parts (221) of the skull, the part lower being made of a material having a modulus of elasticity different from that of the material forming the upper part.

Description

The invention relates to a protective helmet for sports activity. Such activities may include downhill skiing, ski touring or snowboarding. The invention also extends to the practice of climbing, mountaineering, cycling or the practice of snowmobiling. Generally, a helmet forms a protection of the head, to protect the skull of the shocks that it could undergo when the user makes a fall or when an object is projected in its direction.

A classic helmet construction includes an outer shell and an inner cap. The outer shell is generally rigid, and is for example made by molding / injection of a thermoplastic material such as ABS (Acrylonitrile Butadiene Styrene) or PC (PolyCarbonate). Commonly, the inner cap is made of an expanded material such as EPS (Expandable PolyStyrene) or EPP (Expandable PolyPropylene). In order to guarantee good comfort for the user, the helmet is generally equipped with an internal cap which may, for example, be made of foam covered with fabric. The inner cap is attached to the inside of the inner cap.

A helmet is intended to reduce the risk of injury to the skull of the user, while having the least weight possible to not affect the comfort of the user.

To ensure the safety of users, there are several standards generally defining tests and acceptance thresholds that are applied to helmets that are candidates for certification in the associated discipline. Depending on the sporting activity, the normative requirement may differ. Thus, a standard covers a specific activity. From these requirements, there are features that the helmet must provide to provide the required protection. For example, these characteristics correspond to properties of penetration resistance and shock absorption properties, in different areas of the helmet.

For example, the standards EN 1077: 2007 (Europe) or ASTM F2040 (US) apply for the practice of alpine skiing and snowboarding. EN 13781: 2012 (Europe) or FMVSS No. 218 (US) apply to the practice of snowmobiling. Standard EN 12492: 2012 (Europe) applies to the practice of mountaineering and climbing. The standard EN 1078: 2012 (Europe) or 16 CFR Part 1203 - CPSC (US) applies to the practice of cycling.

Current helmets, made by injection, generally comprise an outer shell made of the same material. This construction requires the use of a suitable material to pass the most severe normative constraint to the detriment of other characteristics such as the weight, the efficiency of the damping ...

In addition, it is difficult to design a helmet that meets both resistance to penetration and impact resistance, in particular by maintaining a reduced weight and manufacturing cost.

It is also difficult to use similar designs of helmets for different sports activities, the constraints to be respected, defined in the standards, being, for example, different for the practice of alpine skiing or the practice of the snowmobile. .

Moreover, certification standards may vary depending on the geographical area, so it is difficult to adapt the same helmet geometry to these different standards.

The invention aims to solve one or more of these disadvantages.

An object of the invention is in particular to provide an improved helmet for a sporting practice.

The invention aims in particular to provide a helmet adapted to both penetration resistance and impact resistance constraints, while maintaining a reduced weight and manufacturing cost.

The invention also aims to allow the use of similar designs of helmets and the same manufacturing tools for different helmets for different sports activities, and therefore having to meet different certification standards.

The invention thus relates to a helmet for sporting practice.

The helmet includes an outer shell for positioning on a skull. The outer shell comprises an upper portion for covering at least the top portion of the skull, the material forming the upper portion having mechanical properties adapted for the upper portion to meet a homologation standard defined for the intended use of the helmet and a lower portion secured to the upper part and extending continuously so as to cover at least partially the lateral and posterior parts of the skull, the lower part being made of a material having a modulus of elasticity different from that of the material forming the the top part.

This design optimizes the structure of the outer shell, providing a strengthening of the mechanical properties or damping locally, according to the normative requirements specific to a discipline. We can then have less stressed areas with more flexible characteristics. The result is a lighter and more economical helmet. In addition, by substituting a part of the shell of a helmet dedicated to a discipline by another part made of a different material, one can design a helmet meeting the normative requirements of another discipline.

• Le matériau formant la partie supérieure présente des propriétés mécaniques adaptées pour que la partie supérieure satisfasse la norme d'homologation pour la pratique du ski alpin ou du surf des neiges.
• La dureté Shore D du matériau formant la partie supérieure est comprise entre 50 et 75.
• Le module d'élasticité du matériau formant la partie supérieure est inférieur à 1 000 MPa.
• Le module d'élasticité du matériau formant la partie supérieure est inférieur à celui du matériau formant la partie inférieure.
• La partie supérieure est constituée d'un matériau parmi les matériaux suivants : PU, PP, SBS ou SEBS.
• La partie inférieure est constituée d'un matériau parmi les matériaux suivants : PU, ABS, PP ou PC.
• L'épaisseur de la paroi de la partie supérieure et/ou de la paroi de la partie inférieure est comprise entre un et trois millimètres.
• La coque externe comprend une surépaisseur au niveau d'une zone de jonction entre la partie supérieure et la partie inférieure.
• La surépaisseur est en saillie dans le volume interne de la coque externe.
• L'épaisseur de la zone de jonction est sensiblement égale à la somme des épaisseurs moyennes de chaque partie assemblée.
• La largeur de la zone de jonction est inférieure à trente millimètres.
• Le casque comprend une calotte interne, distincte de la coque externe, la calotte interne étant fixée à l'intérieur de la coque externe.
• La surépaisseur est apte à se loger dans une gorge ménagée dans la calotte interne.

According to advantageous but non-mandatory aspects of the invention, such a front stop may incorporate one or more of the following features, taken in any technically permissible combination:

• The material forming the upper part has suitable mechanical properties so that the upper part satisfies the homologation standard for the practice of alpine skiing or snowboarding.
• The Shore D hardness of the material forming the upper part is between 50 and 75.
• The modulus of elasticity of the material forming the upper part is less than 1000 MPa.
• The modulus of elasticity of the material forming the upper part is smaller than that of the material forming the lower part.
• The upper part consists of one of the following materials: PU, PP, SBS or SEBS.
• The lower part consists of one of the following materials: PU, ABS, PP or PC.
• The thickness of the wall of the upper part and / or the wall of the lower part is between one and three millimeters.
• The outer shell comprises an extra thickness at a junction zone between the upper part and the lower part.
• The extra thickness protrudes into the internal volume of the outer shell.
• The thickness of the junction zone is substantially equal to the sum of the average thicknesses of each assembled portion.
• The width of the junction zone is less than thirty millimeters.
• The helmet comprises an inner cap, distinct from the outer shell, the inner cap being attached to the inside of the outer shell.
• The extra thickness is able to be housed in a groove in the inner cap.

• Un procédé de fabrication d'un casque pour la pratique sportive, incluant une étape de fixation d'une partie inférieure à une partie supérieure par un processus de surmoulage ou par un processus d'injection bi-matière afin de réaliser une coque externe du casque.

The invention also relates to:

• A method of manufacturing a helmet for sporting practice, including a step of fixing a lower part to an upper part by an overmoulding process or a bi-material injection process in order to produce an outer shell of the helmet .

• la figure 1 est une vue en perspective avant d'un casque selon l'invention ;
• la figure 2 est une vue en perspective arrière du casque de la figure 1 ;
• la figure 3 est une vue en perspective de la coque externe ;
• la figure 4 est une vue en coupe médiane de la coque externe ;
• la figure 5 est une vue de détail A de la figure 4 à laquelle la calotte interne a été ajoutée.

Other characteristics and advantages of the invention will emerge clearly from the description which is given hereinafter, by way of indication and in no way limitative, with reference to the appended drawings, in which:

• the figure 1 is a front perspective view of a helmet according to the invention;
• the figure 2 is a rear perspective view of the helmet of the figure 1 ;
• the figure 3 is a perspective view of the outer shell;
• the figure 4 is a median sectional view of the outer shell;
• the figure 5 is a detail view A of the figure 4 to which the inner cap has been added.

In the rest of the description, terms such as "horizontal", "vertical", "longitudinal", "transversal", "superior", "lower", "up", "down", "before" will be used. , " back ". These terms should be interpreted in a relative sense in relation to a helmet worn normally, head straight.

The figure 1 is a perspective view illustrating a helmet 1 for sports practice according to one embodiment of the invention.

The helmet 1 comprises an outer shell 2 and an inner cap 3. The inner cap 3 is housed in the internal volume of the rigid shell 2. It is fixed on the inner face of the rigid shell 2. The inner cap 3 can be covered an internal cap, not shown. The inner cap is for example made of foams surrounded by a fabric or only tissues.

The helmet 1 may also include a retention system, not shown here, including for example a chin strap or a head restraint system.

The helmet 1 is intended to wrap at least part of a skull that the helmet will protect.

In the remainder of the description, several protection zones are defined.

A first protective area 211, referred to as the "crown portion" of the skull, covers the top of the skull. It is defined by an area covering an upper part of the frontal bone and an upper part of the parietal bone.

A second shield area 221, referred to as a "peripheral portion" of the skull, covers the lateral and posterior portions of the skull. The lateral portions are defined by an area at least partially covering the sphenoid bone and the temporal bone. The rear portion is defined by an area at least partially covering the occipital bone.

To ensure the desired protection, depending on the discipline, the helmets must meet specific tests defined by the standard associated with the discipline.

For the practice of alpine skiing and snowboarding, the helmet must withstand puncture tests on the top of the skull and must have adequate cushioning characteristics to withstand impact in one of the frontal, rear, side and top zones. . For impact resistance, a false head is placed inside the helmet and the helmet fitted, in an orientation at the discretion of the laboratory, of a given height. The acceleration measured at the head must remain below a determined threshold value.

For the practice of snowmobiling, the helmet must withstand puncture tests on the top of the skull and must have damping characteristics sufficient to withstand alternately double frontal and lateral impact. It should be noted that the perforation test is more severe than that carried out to homologate a ski helmet.

For the practice of mountaineering, the helmet must withstand puncture tests on the top of the skull and must have damping characteristics sufficient to withstand the impact of a projectile sent to the top of the skull. It should be noted that the perforation test is similar to that carried out to certify an alpine ski helmet.

For the practice of cycling, the helmet must have enough damping characteristics to pass the specific tests. These tests are similar to those performed for the homologation of an alpine helmet.

These requirements emphasize that the expected characteristics of the helmet are not necessarily homogeneous in all areas of the helmets and depend on the discipline exercised.

Thus, the top part of the helmet, corresponding to the first protection zone 211, must have puncture resistance properties and damping properties. The resistance to perforation is mainly achieved by the outer shell. The damping is obtained by the combination of the outer shell and the inner cap.

It emerges that the top part may have different mechanical properties from the other parts in order to optimize the structure while respecting the normative requirements. This is what the invention proposes by modifying the mechanical properties of the outer shell as a function of the protection zones.

In our example, the outer shell 2 has an upper portion 21 for covering at least the first protection zone 211 and a lower portion 22 extending continuously so as to cover at least partially the second protection zone 221. Thus, the outer shell covers, at least in part, the frontal bone, the parietal bone, the occipital bone, the opposite sphenoid bones and the opposite temporal bones.

The upper part 21 can be defined by a minimum surface of the outer shell extending from its top (upper end), when the helmet is worn normally, right head, to a curve defined by the intersection between the outer shell and a plane shifted downward by a distance D of about thirty millimeters from the vertex. This distance D can vary between twenty-five and forty millimeters.

In the example shown, the upper portion extends beyond this minimum area.

The upper portion 21 provides protection against perforation and contributes to the damping in case of shocks.

The lower portion 22 provides satisfactory protection of the lower areas of the skull. It also limits the deformation of the outer shell 2 during side impacts by providing rigidity and resistance to the helmet.

In horizontal section at the level of the ears, the lower portion 22 has a U-shaped shape passing behind the skull.

In an embodiment not shown, it is conceivable that the lower portion 22 belt the skull. In this case, the lower part 22 defined above is extended towards the front of the helmet, then covering an anterior part of the frontal bone. The lower portion 22 thus forms a ring which further stiffens the outer shell 2. As a result, the helmet has a better hold when it is stressed laterally.

The lower portion 22 of the outer shell 2 extends continuously over a width advantageously at least equal to twenty millimeters so as to connect the opposite sphenoid bones through the occipital bone. This width is, for example, between twenty and seventy millimeters in this area.

The lower portion 22 is integral with the upper portion 21. The lower portion 22 and the upper portion 21 are formed in materials having different elastic moduli. With such a configuration, the lower portion 22 provides satisfactory protection of the areas it covers while stiffening the outer shell 2 by attaching it to the upper part 21. This rigidity brings the helmet to hold and avoids a sag of the upper part 21 which is connected to it. The attachment to the upper part 21 promotes the impact resistance of the outer shell 2.

In the embodiment illustrated here, the lower portion of the cap 2 is continuously attached to the upper portion 21 from a sphenoid bone to the opposite sphenoid bone through the occipital bone. The upper part and the lower part thus form a single piece. This promotes structural cohesion between the upper 21 and lower 22 and therefore a better mechanical grip between the two parts. To obtain this outer shell monobloc, it is preferentially used overmolding process or bi-injection, as will be detailed later. The helmet thus comprises an overmolded or bi-injected outer shell, which gives it characteristics optimized to meet the standards of the targeted discipline.

In a variant, the two parts can be removable between them, which makes it possible to change one part for another having different mechanical properties or if the part exchanged is damaged.

For a helmet 1 intended for the practice of alpine skiing or snowboarding, the upper part 21 is formed of a material having mechanical properties promoting a resistance to perforation, while the lower part 22 is formed in a material having a superior modulus of elasticity, to promote stiffness and impact resistance.

Moreover, the damping characteristics of the helmet at the top impacts are generally dimensioning for the helmets. They are mainly determined by the mechanical properties of the inner cap. However, the outer shell also influences these damping properties of the helmet. In most existing helmets, the outer shell is mono material and very rigid, especially in the first protection zone. This stiffness penalizes the damping of the helmet for vertical shocks. The invention, applied to the alpine ski helmet, proposes to use a softer material, at least, at the first protection zone 211. Being more flexible, a portion of the vertical shock is absorbed by the outer shell. In addition, by being connected to a lower rigid part, the upper part can flare to damp the vertical shock.

To obtain a good behavior of the helmet and in particular for a good damping, the upper part 21 is made of a flexible material having a modulus of elasticity or Young's modulus between 100 and 1000 MPa. To characterize a flexible material, one can consider the tensile stress at 100% elongation. For this upper part, this stress is preferably between 20 and 50 MPa. The Shore D hardness of the material is advantageously between 50 and 75. It may be a PU (Polyurethane), a PP (PolyPropylene), an SBS (Styrene-Butadiene-Styrene) or an SEBS (Styrene-Ethylene / Butylene- styrene).

Very good results have been obtained by making this upper part with Desmopran® DP 9855 DU or IRFRAN® MR 1301-010 or IRFRAN® MR 1301-030.

Advantageously, the wall thickness of the upper portion 21 of the shell 2 is between one and three millimeters.

To obtain good strength of the helmet, the lower portion 22 is made of a rigid material having a modulus of elasticity or Young's modulus between 900 and 2500 MPa. It can be PU (Polyurethane), ABS (Acrylonitrile Butadiene Styrene), PP (PolyPropylene) or PC (PolyCarbonate).

Advantageously, the wall thickness of the lower portion 22 of the shell 2 is between one and three millimeters.

To obtain a good damping of the helmet, it is preferable that the modulus of elasticity, or Young's modulus, of the material forming the lower part 22 is less than one and a half times greater than that of the material forming the upper portion. Advantageously, this ratio is greater than two.

It can be envisaged that the upper portion 21 and the lower portion 22 have the same thickness, of the order of two millimeters. It can also be envisaged that the lower and upper parts have different thicknesses, in order to stiffen certain areas.

The average thickness of the outer shell, apart from the local extra thicknesses, is less than five millimeters.

The upper portion 21 is advantageously sized to withstand the perforation tests of the EN 1077: 2007 standard for alpine helmets. A material of sufficient thickness and sufficiently resilient is for example used to form the upper part 21 of the outer shell 2.

The helmet 1 can be designed to meet homologation standards defined for different sports, for example downhill skiing, snowmobiling, mountaineering or cycling.

Due to the use of two different materials for the upper part 21 and the lower part 22, the characteristics of the helmet can be adapted to the targeted activity, while maintaining the same helmet geometry. Generally, it is enough to change the upper part according to the intended application. For example, for snowmobiles, it is necessary to reinforce the resistance to the perforation. For climbing, it is necessary to improve the projectile impact resistance. By his knowledge, a person skilled in the art can determine which material is most suitable for the upper part to satisfy a homologation standard defined for a particular use of the helmet. From the norms, he can deduce the mechanical properties that must be targeted in the choice of the material of the upper part.

This design makes it possible to envisage common tools for making common parts or parts using materials having similar formatting parameters.

In addition, with an outer shell provided with areas of materials having different mechanical properties, the design can be optimized to locally obtain, where necessary, improved strength and / or damping, while maintaining a lighter structure. We can also size the outer shell to allow the homologation of the helmet in several disciplines without greatly penalizing the weight. Such a helmet then meets several standards.

It may be envisaged that the lower part 22 may comprise several zones made of different materials in order, for example, to locally reinforce the structure of the outer shell.

To make a helmet, there are two main technologies.

A first technology, called injection, consists of producing the outer shell and the inner cap separately. Thus, the inner cap 3 is distinct from the outer shell 2. In a second step, the inner cap is assembled in the outer shell by appropriate connecting means such as clips, fasteners, rivets, glue, VELCRO hooks ... This technology offers the possibility to separate the inner cap of the outer shell if necessary. This may be useful, for example, to replace a deteriorated part.

A second technology, called thermoforming or "in-mold", consists of producing the outer shell at first. In a second step, the shell is placed inside a mold in which a material is injected to produce the inner cap. Thus, the inner cap is directly connected to the outer shell to form a one-piece piece having an average thickness greater than five millimeters. This chemical grip is indémontable. It allows an excellent connection between the two parts.

The invention applies to helmets made according to the first technology for which an outer shell is made independently of the inner cap, the outer shell comprising at least two upper and lower parts made of different materials.

Advantageously, the outer shell is made by an overmolding or bi-injection process. These technologies make it possible to obtain a one-piece shell. The chemical grip between the upper and lower parts is very good. The shell then has good mechanical strength and does not require or little recovery which provides an economical finish, suitable for the desired aesthetic.

The overmolding process consists in injecting, firstly, a first part. This first part forms an insert which is then placed in a mold into which the second part is injected.

The bi-injection process consists in simultaneously injecting the two materials into the same mold, in order to produce the complete shell. This technology makes it possible to obtain a better mechanical and chemical grip between the two parts. However, the price of tools is greater than for overmolding technology.

For the injection to go well, it is advantageous that each part of the shell has a substantially constant thickness. At the junction zone 23 between the two parts, an excess thickness 24 is provided so that the two materials can mix better in order to increase the chemical and mechanical adhesion between the two parts.

In this example, the junction zone 23 extends over a width of less than thirty millimeters. The thickness of this zone is substantially equal to the sum of average thicknesses of each assembled part. Advantageously, it is less than four millimeters not to weigh down the helmet.

Advantageously, this extra thickness 24 projects in the internal volume of the outer shell 2. In other words, the extra thickness protrudes from the inner surface of the outer shell 2 and extends inside said shell, in the direction of the outer shell. the user's head when the helmet is worn. Thus, the outer surface of the outer shell is continuous, without asperities, which is sought for the aesthetics and aerodynamics of the helmet.

The inner cap 3 here comprises a groove 31 intended to receive the excess thickness 24. Thus, the cooperation between the excess thickness 24 and the groove 31 promotes a relative positioning between the outer shell 2 and the inner cap 3, during the assembly of the helmet 1. In addition, this allows a certain relative maintenance between the two parts, this cooperation limiting a relative movement of the cap relative to the hull. Note that the current helmet designs do not facilitate a precise positioning of the inner cap relative to the outer shell.

Moreover, the excess thickness 24 makes it possible to form a stiffening strip at the junction between the upper part 21 and the lower part 22. This rigidity contributes to the good strength of the helmet and prevents sagging of the helmet when it is stressed.

In the illustrated embodiment, the inner cap 3 forms an envelope covering a portion of the skull. This envelope comprises in its inner part recesses 32 intended to receive removable cushions 4. These cushions are fixed on the inner cap, in these recesses 32, by suitable fastening means, for example, an adhesive tape or hooks VELCRO type . The cushions are deformable. It can be mosses. These removable cushions are preferably positioned on the front part, the lateral parts, the rear part and the summit part of the inner surface of the inner cap. These cushions are used to improve the wearing comfort by allowing the setting of the helmet on the morphology of the skull of the user. Thus, by changing only the cushions, one can adapt the internal interface of the helmet to different types of skull morphology, for example, circular / ovoid. In addition, cushions can also be used to help dampen shocks by using suitable materials.

In this example, the helmet is shown without provision for ventilation. Of course, the helmet may include such arrangements in the form of openings in the outer shell 2 and air ducts dug in the inner cap 3.

In the examples, the outer shell is monobloc which allows to have a unitary piece having its own holding and therefore easier to handle.

In a variant, the outer shell 2 is made by overmolding or bi-injection and the inner cap 3 is assembled to the outer shell by thermoforming, "in-mold" technology. In this case, the inner cap 3 is continuously secured to the outer shell 2. It is not removable. This strengthens the cohesion between the elements of the helmet which makes the helmet unit more solid.

The invention is not limited to these embodiments. It is possible to combine these embodiments.

The invention is not limited to the embodiment previously described but extends to all the embodiments covered by the appended claims.

Claims (15)

Helmet for sporting practice (1), characterized in that it comprises an outer shell (2) intended to be positioned on a skull, the outer shell including: an upper part (21) intended to cover at least the summit part (211) of the skull, the material forming the upper part having suitable mechanical properties so that the upper part satisfies a homologation standard defined for the intended use of the skull; helmet ; and - a lower portion (22) integral with the upper part so as to form a single piece, the lower portion extending continuously to cover at least partially, the lateral and posterior parts (221) of the skull, the part lower being made of a material having a modulus of elasticity different from that of the material forming the upper part. Helmet (1) according to claim 1, characterized in that the material forming the upper part has suitable mechanical properties so that the upper part meets the homologation standard for the practice of alpine skiing or snowboarding. Helmet (1) according to one of the preceding claims, characterized in that the Shore D hardness of the material forming the upper part (21) is between 50 and 75. Helmet (1) according to one of the preceding claims, characterized in that the modulus of elasticity of the material forming the upper part (21) is less than 1000 MPa. Helmet (1) according to one of the preceding claims, characterized in that the modulus of elasticity of the material forming the upper part (21) is smaller than that of the material forming the lower part (22). Helmet (1) according to one of the preceding claims, characterized in that the upper part (21) consists of one of the following materials: PU, PP, SBS or SEBS. Helmet (1) according to one of the preceding claims, characterized in that the lower part (22) consists of one of the following materials: PU, ABS, PP or PC. Helmet (1) according to one of the preceding claims, characterized in that the thickness of the wall of the upper part (21) and / or the wall of the lower part (21) is between one and three millimeters. Helmet (1) according to any one of the preceding claims, characterized in that the outer shell comprises an extra thickness (24) at a junction zone (23) between the upper part and the lower part. Helmet (1) according to the preceding claim, characterized in that the extra thickness (24) is projecting into the internal volume of the outer shell (2). Helmet (1) according to one of claims 9 or 10, characterized in that the thickness of the junction area (24) is substantially equal to the sum of the average thicknesses of each assembled portion (21, 22). Helmet (1) according to one of claims 9 to 11, characterized in that the width of the junction zone (24) is less than thirty millimeters. Helmet (1) according to one of the preceding claims, characterized in that it comprises an inner cap (3), distinct from the outer shell (2), the inner cap being fixed inside the outer shell. Helmet (1) according to one of claims 9 to 12 combined with claim 13, characterized in that the extra thickness (24) is adapted to be housed in a groove (31) formed in the inner cap (3). A method of manufacturing a helmet for sporting practice (1), including a step of fixing a lower part (22) to an upper part (21) by an overmolding process or a bi-material injection process to realize an outer shell (2) of the helmet.

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