The invention is related to a helmet having an outer shell, wherein the shell is constructed from an in-mold shell portion and a post-applied shell portion, and to the method of making the helmet.
Conventional helmets typically include a hard exterior shell and a foam liner interior to the shell. There are two widely-used methods of making a helmet with a liner and shell. In one method, the hard outer shell and the foam liner are both made independently of each other. Thereafter, the shell is applied to the liner with glue, rivets, screws or is otherwise attached by physical means. As used throughout this application, “post-applied shell” refers to a shell or shell portion attached to the foam liner, after the foam liner has been pulled from the mold, and such technique is referred to as the “post-applied method.” In a second method, the helmet's hard outer shell is bonded to the helmet's inner foam liner simultaneously with the formation of the liner. The liner is cast with the shell in the mold. The liner material, typically polystyrene, is injected into the mold containing the hard outer shell. As used throughout this application, “in-mold shell” refers to a shell or shell portion that is bonded to the foam liner at the time of formation of the foam liner, and such technique is referred to as the “in-mold method.” The advantage with the latter method is that the in-mold method results in a sturdier attachment between the shell and the liner that can prevent separation of the shell from the liner under a severe impact. The former method, however, is not without advantages.
While the in-mold method has a distinct advantage in strength, the post-applied method also has an advantage that cannot be fully realized in a helmet with an in-mold shell. For example, independently forming the liner and the shell, and thereafter, attaching the shell to the liner, after formation of the liner, permits the creation of channels on the exterior surface of the liner (i.e., the surface facing the shell). Thus, when the shell and liner are brought together, the channels on the liner are converted into conduits between the shell and liner that are useful for providing ventilation. Air flow between the shell and the liner is not possible with a helmet having an in-mold shell, since all the interior surfaces of an in-mold shell are covered with the foam liner as a result of the method used.
Accordingly, there is a need to provide a sturdy in-mold shell helmet with the ventilation advantages of a post-applied shell helmet. Alternatively, there is a need for a sturdy shell to liner attachment in a post-applied shell helmet. The present invention fulfills these needs and has further related advantages.
The present invention is related to a helmet having an interior foam liner and at least two shell portions exterior to the liner. The helmet includes an exterior in-mold shell portion covering a portion of the liner. The helmet also includes an exterior post-applied shell portion covering a portion of the liner that is not covered by the in-mold shell portion. In one embodiment, the in-mold shell portion comprises polycarbonate and the post-applied shell portion comprises poly(acrylonitrile-butyl-styrene). The helmet includes conduits located between the liner and the exterior post-applied shell portion for ventilation and air flow for removing the heat generated by a user. The liner is made with channels and through-bores that form the various air entry and exit points and the conduits of the helmet. The exterior post-applied shell portion includes holes and vent fins to assist in the entry, exit, and direction of the air flow through the conduits.
A method of making a helmet having a liner and a shell includes placing a first shell portion in a mold and making a casting of a foam liner to provide a liner with an in-mold shell portion bonded to the liner and partially covering a portion of the liner that is desired to have a sturdy attachment between the in-mold shell and the liner. After removing the liner from the mold, the method includes attaching a second shell portion to the liner portions that are not covered by the in-mold shell portion. Because the liner has been provided with channels and through-bores, the application of the post-applied shell portion results in conduits and entry and exit points for the air that are created from the post-applied shell portion and the liner.
The helmet made in accordance with the invention provides numerous advantages, including the ability to provide ventilation between the shell and the liner where ventilation is important, but also provides a structurally stout attachment between the shell and the liner where the integrity of the shell and liner attachment is important or alternatively, where ventilation is unimportant.
The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:
Generally, helmets include an interior shock absorbent liner made from a material capable of being foamed, such as polystyrene, polyurethane, or other similar materials, and an exterior hard shell made from materials, such as polycarbonate and poly(acrylonitrile butadiene-styrene) (ABS).
A first conventional method of producing a liner with a shell includes casting the foam liner with the entire shell in the mold. After curing, the foam liner is pulled from the mold with the in-mold shell integrally bonded to the foam liner. Additionally, other helmet components besides the entire shell can be cast with the foam liner to integrally embed the helmet components in the liner. In the in-mold method, all interior surfaces of the shell are exposed to the foam and are, therefore, bonded to the foam liner. The in-mold method leaves no spaces between the interior surface of the shell and the foam liner, thereby providing a very sturdy attachment that can withstand a severe impact. However, the advantage of the in-mold method also results in a helmet that cannot be provided with venting between the shell and the liner for the very reason that all interior surfaces of the shell are fully covered by the foam. Venting between the shell and the liner is desirable in some instances for increasing the rate of heat removal from the body.
A second conventional method of producing a liner with a shell includes manufacturing the liner and the entire shell independently of one another and then bonding or otherwise attaching the entire shell to the liner with an adhesive or through the use of rivets, screws or other hardware. The liner is typically made by injecting or pouring polystyrene granules inside of a mold and allowing the polystyrene to expand to the shape of the mold. A mold release can be applied to the mold surface, prior to casting the liner for separating the liner from the mold. The positive mold can be provided with any number of ridges and protrusions, which result in channels and through-bores in the negative foam liner casting that is removed from the mold. Once the foam liner is removed from the mold, the shell can be bonded to the foam liner.
In the post-applied method, it is not necessary that the shell have the exact contours of the foam liner. If venting is desired between the shell and liner, it is advantageous that the shell does not have the exact contours so that conduits can be formed between the shell and the liner out of the channels in the liner to allow for airflow therein. In direct contrast to the post-applied method for making a helmet, the in-mold method of making a helmet is not suitable for creating spaces for air flow between the shell and the liner. This is because the in-mold method exposes all the interior surfaces of the shell to the foam liner. While it is possible to put apertures that extend through both the shell and the liner in an in-mold helmet, it is not possible to provide channels for airflow between the shell and the liner. In some instances, apertures that extend through both the shell and the liner are insufficient to remove the heat generated by a user.
According to the present invention, a helmet with a liner is provided that has at least one in-mold shell portion and at least one post-applied shell portion. The advantages of each shell type can be exploited by locating the post-applied shell portion or portions where ventilation between the shell and liner is desired, for example, at the coronal or frontal areas of the helmet. The coronal area is desirable because heat rises, and the frontal area is desirable because air impacts the front of the helmet. The in-mold shell portion or portions can be applied to the remainder of the liner not covered by the post-applied shell or where ventilation is of relatively minor importance. Alternatively, the in-mold shell portion or portions can be applied to the areas where a sturdy attachment between shell and liner is desired to protect the most sensitive areas of the head. In one embodiment of the invention, for example, an in-mold shell portion can be applied at the occipital area of the helmet because air does not impact the helmet in the occipital area as compared with the frontal or coronal area. It is also possible to have overlapping portions at the boundaries of the in-mold and post-applied shell portions. One or more in-mold shell portion or portions and one or more post-applied shell portion or portions can be applied to the helmet. In other embodiments, it is possible that the in-mold shell portion can be applied at other locations besides the occipital area. For example, the in-mold shell portion can be applied to the temporal, frontal or coronal areas of the helmet. Besides a monolithic in-mold shell portion, more than one in-mold shell portion can be applied to any one or more portions of the liner. Similarly, the post-applied shell portion can be a monolithic shell portion, or alternatively, post-applied shell portions can be applied at distinct areas of the liner. Generally, terms such as occipital (back), coronal (top), temporal (side) and frontal (front) denote areas of the skull, as used herein however, the terms are used to denote areas on the liner, shell or helmet that are in proximity to these corresponding areas of the skull. It is to be appreciated when referring to locations that designations such as occipital, temporal, coronal, and frontal give only approximate locations. Also, directions, such as upper, lower, bottom or side, are to be taken in the context of the application figures and are not limiting.
Referring now to
Referring now to
The areas of the liner 112 not covered by the in-mold shell portion 102 are exposed foam and may be provided with a variety of features, including channels and through-bores. The in-mold method results in the absence of voids between the inner, major surface of the in-mold shell portion 102 and the outer, major surface of the liner 112. Accordingly, where ventilation between the shell and liner is desired, no in-mold shell portion has been provided. As seen in
Referring now to
The post-applied shell 104 may define the entry points and exit points for air when the shell 104 is applied to the liner 112. Holes 158, 160 may be provided for air entry due to their placement at the frontal area where air impact is at its greatest, while vent fins 172 and 174 may lie at the air flow exit at the occipital area, when combined with liner 112 and in-mold shell portion 102. The post-applied shell 104 may provide cover for the areas that are not covered by the in-mold shell portion 102, excepting some overlap at the boundary region between the in-mold shell portion 102 and the post-applied shell portion 104 that creates an overhang 170 at the occipital area of the helmet 100 as seen in
Referring now to
Referring now to
While the preferred embodiment of the invention has been illustrated and described, it will be appreciated that various changes can be made therein without departing from the spirit and scope of the invention.
This application claims the benefit of provisional U.S. Application No. 60/527,452, filed on Dec. 5, 2003, incorporated herein expressly by reference.
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