EP3485752A1 - Helmet - Google Patents

Abstract

The invention relates to a helmet (11) comprising a helmet body (15), a ventilation hole (17), a cover (19) which at least partially covers the ventilation hole (17), an energy store (32) and a cover (19 ) provided photovoltaic cell (22) for charging the energy storage device (32).

Description

The present invention relates to a helmet, for example a bicycle helmet, with a helmet body, a ventilation hole, a cover which at least partially covers the ventilation hole, and an electrical energy store.

Such a helmet serves the safety of a wearer of the helmet, for example a cyclist. However, it is self-evident that the use of such a helmet is not limited to cyclists, even riders of a unicycle, quads, motorcycles, scooters, skateboards or users of inline skates or the like can wear such a helmet.

Ventilation holes in the helmet body contribute to an increase in wearing comfort, as this air can circulate on the head of the helmet wearer. By one or more ventilation holes covering covers the helmet carrier is protected from micro parts, which can penetrate into the ventilation holes, such as insects, Aststückchen or the like. In addition, the ventilation effect of the ventilation holes can be improved by a special design of the covers.

The integrated into the helmet energy storage is used to supply a power consumer with energy, such as a built-in helmet rear light, which should improve the visibility of the helmet wearer even in poor visibility, for example, at night, in a tunnel or fog. Usually, such a tail light is attached to a back of the helmet, for example, by being inserted in a recess provided in the helmet body or attached to an outer surface of the helmet.

The energy store is typically in the form of a battery integrated in the backlight. Here, however, there is the problem that the battery has only a limited life, which is the shorter, the more often the rear light is used. To prevent inadvertent extinction of the tail light during use of the helmet, the user of the helmet must therefore replace the battery regularly. However, this proves to be uncomfortable in practice.

It is therefore an object of the invention to provide a helmet with an energy storage that can provide reliable energy permanently.

The object is achieved by a helmet having the features of claim 1 and in particular by at least one photovoltaic cell for charging the energy store, which is provided on the cover.

The invention is based on the general idea to equip the helmet with a rechargeable energy storage and a photovoltaic cell for charging the energy storage. In normal use of the helmet, that is not exclusive use and storage of the helmet in darkness, this ensures that the energy storage always has enough energy to power a connected power consumers with energy.

By the automated charging of the energy storage, such as a built-in helmet or attached to the helmet accumulator by means of the photovoltaic cell the user of the helmet remain uncomfortable battery replacement and associated costs spared.

A plurality of photovoltaic cells can be combined in a solar module in order to provide a voltage or a sufficient current required for charging the energy store. Furthermore, the at least one photovoltaic cell can in principle be permanently connected to the energy store. In this case, however, an example of defect-related replacement of photovoltaic cell and / or energy storage is only possible together. Preference is therefore given to a design in which the at least one photovoltaic cell and the energy storage are releasably connected to each other, for example by means of a plug connection, so that if necessary, an individual exchange of photovoltaic cell or energy storage is possible.

By their attachment to the cover, the assembly or disassembly of the photovoltaic cell is simplified because it can be attached to the helmet body together with the cover, which is typically formed like the photovoltaic cell in this way. In other words, the cover serves as a support structure for the photovoltaic cell and thus fulfills a dual function in that at the same time it also at least partially covers the associated ventilation hole in order to prevent the penetration of microparts and, if appropriate, the aerodynamics and / or the ventilation effect, i. ultimately to optimize the air circulation at the head of the helmet wearer. As ventilation hole in this context, an opening to understand, which extends from an inner side of the helmet through the helmet body to an outside of the helmet.

In order that the provided with the photovoltaic cell cover can still cause a desired air inlet and desired turbulence of the wind, the surface of the photovoltaic cell is preferably smaller than the surface of the cover and chosen in particular so small that covered by the cover ventilation hole or more through the cover Covered ventilation holes is not completely closed or closed by the photovoltaic cell.

The helmet body can be made, for example, from a rigid foam, in particular expanded polystyrene rigid foam, hard foam being particularly well suited for absorbing shocks. The helmet body may further be at least partially provided with an outer shell, which is made for example of a thermoplastic such as polyvinyl chloride, polyethylene terephthalate, polycarbonate or acrylic-butadiene-styrene. The helmet body may be connected, for example by gluing, molding or foaming with an inner side of the outer shell.

Advantageous embodiments of the invention are described in the dependent claims, the description and the drawings.

According to a first embodiment, the cover is detachably attached to the helmet. The releasable connection can be realized for example by means of snaps, a hook and loop fastener or a zipper. The detachable connection makes it easy to attach the cover and photovoltaic cell to the helmet. Once the photovoltaic cell and cover are not needed, they can easily be removed from the helmet. In heavy rain they can also be removed and replaced by a rain cover. Basically, common rain covers for the helmet can also be created on the cover and photovoltaic cell. It is also possible that the helmet was initially shipped with a detachable cover without a photovoltaic cell. Due to the detachable connection between the helmet and cover then a simple retrofit can be made by a cover with photovoltaic cell.

It is particularly advantageous if the cover has a grid structure with a multiplicity of openings. By means of the grid structure, turbulences of the wind are generated, whereby a ventilation effect of the or each under the cover located ventilation hole is improved. Such a grid structure may be made of a plastic or metal material, for example.

Preferably, the openings are smaller than the or each vent hole. The openings may e.g. be designed as micro-openings, which have a diameter in the micrometer range. The fact that the openings are smaller than the or each ventilation hole, on the one hand the ventilation effect of the cover and on the other hand, the protection against penetrating insects or the like can be improved.

According to a further embodiment, the cover is a curved structure and / or rigid in itself. Due to the curved design of the cover this can be adapted to the shape of the helmet. In particular, the curvature can be convex and follow the contour of the helmet. In addition, the cover can be stiff in itself. As a result, the strength of the cover is increased and also protects the photovoltaic cell, since the cover does not yield to an external force.

Preferably, the photovoltaic cell is absorbed by the cover deformation-free. This means that the photovoltaic cell can be attached to the cover without being deformed, for example, bent, thereby preventing breakage or other damage to the photovoltaic cell.

According to a particularly advantageous embodiment, the photovoltaic cell is arranged in the region of an apex of the helmet. Under the vertex The helmet is the highest point on the top of the helmet to understand. Due to the orientation of the photovoltaic cell in this area, when the helmet is worn during the day an optimal incidence of light and thus optimum energy supply into the energy store are made possible. However, for example, for the way to and from work, the cover can in principle also be positioned so that the orientation of the photovoltaic cell is adapted to the respective incidence of light. In this way, the respective incidence of light can be optimally utilized even in the early morning hours and in the late evening hours.

According to a further embodiment, the photovoltaic cell is connected directly or indirectly to the energy store. A direct connection of the photovoltaic cell with the energy storage can be realized for example by means of a power cable. In the case of an indirect connection, for example, a control unit can be connected between the photovoltaic cell and the energy store. Also, the control unit may each be connected by means of a suitable electrical line, e.g. be connected by means of a power cable to the photovoltaic cell and the energy storage. Of course, instead of the power cable another electrical conductor can be used. Furthermore, a read-out unit and / or a counting unit can be connected between the photovoltaic cell and the energy store.

In addition, the energy storage device can have a connection by means of which the energy store can also be charged externally. Such a connection can be designed, for example, in the form of a USB socket. Due to the possibility of additional external energy supply, a sufficient state of charge of the energy storage can be ensured even at low incidence of light.

It when the energy storage is arranged in a recess of the helmet body, in particular together with an associated power consumers is particularly advantageous. By accommodating the energy store in the helmet body, on the one hand, a secure housing is realized, on the other hand, a streamlined shape of the helmet can be maintained, since the energy storage does not have to be mounted on the outer shell of the helmet. By a force and / or positive fit of the energy storage in the recess of the energy storage can be effectively protected against falling out and thus possible damage or even loss. In addition, a power consumer associated with the energy storage device may be arranged in the same or an adjacent recess. The recess is advantageously arranged on a rear side of the helmet, in particular if the current consumer is a tail light.

Preferably, a power cable for connecting the energy store with the photovoltaic cell and / or the power consumer at least partially passes through a channel of the helmet body. In particular, a power cable may be led from the photovoltaic cell through a vent hole into the helmet interior or into the helmet body. Through a channel from the ventilation hole to the energy storage device located in the recess, an electrical connection can be realized without the helmet wearer experiencing a loss of comfort due to the power cable.

If the energy store and the power consumer are accommodated in a common recess, a power cable connecting them can also be routed through a channel in the helmet body.

Preferably, the connection of a power cable to the photovoltaic cell, the energy storage and / or the power consumer by means of a detachable plug connection.

The power consumer, the energy storage and / or the control unit and these connecting lines can be arranged in a common housing, in particular of the power consumer. As a result, a compact component is created, which can be easily inserted into the helmet body and connected, for example by means of a power cable to the photovoltaic cell.

According to an advantageous embodiment, the power consumer is an optical or acoustic output unit. As already mentioned, the current consumer can be embodied in particular in the form of a helmet tail light, by means of which the visibility of the helmet wearer in traffic is improved. Preferably, such a helmet tail light is arranged in a recess on the helmet back.

However, the power consumer can also be designed as an acoustic output unit, for example as speakers or headphones. In principle, the power consumer may also be any other electrical or electronic component, for example a charger, e.g. for a mobile phone, or even a sensor, in particular for a safety application, such as for the detection of an accident. Another power consumer could also give a signal by means of which an accidental helmet wearer can be located.

Fig. 1

zeigt einen Fahrradhelm gemäß einer ersten Ausführungsform der Erfindung von oben.

Fig. 2

zeigt einen Fahrradhelm gemäß einer zweiten Ausführungsform der Erfindung ohne Energiespeicher und Verkabelung von unten.

Fig. 3

zeigt den Fahrradhelm von Fig. 2 mit Energiespeicher und Verkabelung von unten.

Fig. 4

zeigt eine Detailansicht der Fig. 3.

Fig. 5

zeigt einen Fahrradhelm gemäß einer dritten Ausführungsform der Erfindung von unten.

The invention will be described purely by way of example with reference to possible embodiments with reference to the accompanying drawings.

Fig. 1

shows a bicycle helmet according to a first embodiment of the invention from above.

Fig. 2

shows a bicycle helmet according to a second embodiment of the invention without energy storage and cabling from below.

Fig. 3

shows the bicycle helmet of Fig. 2 with energy storage and wiring from below.

Fig. 4

shows a detailed view of Fig. 3 ,

Fig. 5

shows a bicycle helmet according to a third embodiment of the invention from below.

The in Fig. 1 shown helmet 11 has an outer shell 13 and a recorded in the outer shell 13 helmet body 15. The outer shell 13 is preferably made of a thermoplastic elastomer - for example, polyvinyl chloride or acrylic-butadiene-styrene - manufactured. The helmet body 15 may be formed of a hard foam - for example, an expanded polystyrene foam - and glued to the outer shell 13 or injected or foamed into the outer shell 13. The outer shell 13 surrounds the helmet body 15 at least partially. The helmet body 15 is shock absorbing, the outer shell 13, however, inherently stiff. Through the combination of outer shell 13 and helmet body 15, a wearer of the helmet is best protected against injury in the head area in the event of an accident.

Ventilation holes 17 pass through the helmet 11 and thus both the outer shell 13 and the helmet body 15. The ventilation holes 17 are formed and arranged in a conventional manner in order to optimize the ventilation effect and thus to increase the comfort of wear for the helmet wearer.

As Fig. 1 shows a cover 19 is placed on the outer shell 13 of the helmet 11 and releasably secured thereto. The releasable attachment, for example be realized by means of snaps, Velcro, eyelet hook systems or the like. The cover has a grid structure with a plurality of openings 21. The openings 21 are dimensioned smaller than the ventilation holes 17 and provide a turbulence of the airstream. In order to enhance the effect of turbulence, the cover 19 covers several ventilation holes 17.

The cover 19 is formed as a rigid structure and this purpose made of a suitable rigid plastic or metal material. The cover 19 is adapted by a corresponding curvature of the shape of the outer shell 13.

The cover 19 carries a solar module 23, which has a plurality of photovoltaic cells 22. Specifically, the solar module 23 is pushed into a pocket of the cover 19 and thus absorbed without deformation in the cover 19, whereby, inter alia, a fracture of the solar module 23 is prevented. It is understood, however, that for attaching the solar module 23 to the cover 19, a variety of other form-fitting, non-positive and / or cohesive mounting options come into question, for. Plugging, gluing, latching, screwing, etc.

The solar module 23 is dimensioned so large that not all of the covered by the cover ventilation holes 17 are covered by the solar module 23. As a result, an optimal ventilation effect is achieved even when mounted solar module 23.

In order to ensure maximum light incidence on the solar module 23, the solar module 23 is positioned in the region of a vertex S of the helmet 11. In a recess 27 on a rear side R of the helmet 11, a power consumer in the form of a helmet tail light 25 is arranged. As Fig. 1 shows, the helmet rear light 25 has a substantially triangular base body.

The shape of the cover 19 is not limited to the shape of the Fig. 1 Limited cover 19 shown, but a variety of different geometries is conceivable. The grid structure of the cover 19 may vary from helmet to helmet. For example, depending on the application, different sizes and shapes of openings 21 can be selected and / or combined with one another

Fig. 2 shows a second embodiment of a helmet 11 with outer shell 13 and helmet body 15 from below, which like the helmet 11 of Fig. 1 an outer shell 13, a helmet body 15, a plurality of ventilation holes 17 and a cover 19 with solar module 23 has. At a rear side R of the helmet 11, a first recess 27 is formed in the helmet body 15, in which a helmet rear light 25 is arranged. The first recess 27 in this case penetrates both the helmet body 15 and the outer shell 13, so that the integrated into the first recess 27 helmet rear light 25 is visible from the outside.

Adjacent to the first recess 27 is a second recess 29, which is arranged between the first recess 27 and the solar module 23 mounted on the cover 19.

The second recess 29 serves to receive an energy store ( Fig. 3 and 4 ), specifically a rechargeable battery 32. The rechargeable battery 32 is charged by means of the solar module 23 and supplies the current consumer, in this case the helmet rear light 25, with power. For this purpose, the accumulator 32 is connected to the solar module 23 by means of a first cable piece 33, which extends through one of the ventilation holes 17 and a first cable channel 35. The first cable piece 33 is connected by means of plug connections 37 to the solar module 23 and the accumulator 32. By means of a second cable piece 39 which extends through a second cable channel 41, the accumulator 32 is connected to the helmet rear light 25. The second cable piece 39 is connected by means of connectors 37 to the accumulator 32 and the helmet rear light 25. In order to be able to charge the accumulator 32 by means of another, external energy source, the accumulator 32 can have a further connection (not shown), for example in the form of a USB socket.

Fig. 5 shows a third embodiment, which differs from the in Fig. 3 2 shows that a control unit 43 is connected between the solar module 23 and the accumulator 32. By means of the control unit 43, for example, the charging process of the accumulator 32 can be controlled and its energy level can be read out.

In addition, the first recess 27 and the second recess 29 are integrated with each other in such a way that they form a common recess 28 and the second cable channel 41 can be omitted. In the third embodiment, the accumulator 32 and the helmet rear light 25 are thus in the common recess 28.

According to an embodiment, not shown, the accumulator 32, the control unit 43, the helmet rear light 25 and the cable pieces 39 may be accommodated for connecting the aforementioned components in a common housing.

LIST OF REFERENCE NUMBERS

11

helmet

13

outer shell

15

helmet body

17

vent hole

19

cover

21

openings

22

photovoltaic cell

23

solar module

25

Helmet taillight

27

first recess

28

common recess

29

second recess

32

accumulator

33

first cable piece

35

first cable channel

37

connector

39

second cable piece

41

second cable channel

43

control unit

R

Rear of the helmet

S

Vertex of the helmet

Claims (14)

A helmet (11), for example a bicycle helmet, comprising a helmet body (15), a ventilation hole (17), a cover (19) which at least partially covers the ventilation hole (17), and an electrical energy store (32).
marked by
a photovoltaic cell (22) for charging the energy storage device (32) provided on the cover (19). Helmet (11) according to claim 1
characterized in that
the cover (19) is releasably attached to the helmet (11). A helmet (11) according to claim 1 or 2,
characterized in that
the cover (19) has a grid structure with a plurality of openings (21). A helmet (11) according to claim 3,
characterized in that
the openings (21) are smaller than the ventilation hole (17). A helmet (11) according to claim 3 or 4,
characterized in that
the grid structure is arched
and or
the lattice structure is rigid in itself. Helmet (11) according to at least one of the preceding claims,
characterized in that the photovoltaic cell (22) is received without deformation of the cover (19). Helmet (11) according to at least one of the preceding claims,
characterized in that the photovoltaic cell (22) is arranged in the region of a vertex (S) of the helmet (11). Helmet according to at least one of the preceding claims,
characterized in that the photovoltaic cell (22) is connected directly or indirectly to the energy store (32). Helmet (11) according to at least one of the preceding claims,
characterized in that the energy store (32) by means of a first cable (33) to the photovoltaic cell (22) is connected, in particular wherein the first cable (33) at least partially in a first channel (35) of the helmet body (15). Helmet (11) according to at least one of the preceding claims,
characterized in that the energy store (32) in a recess (27) of the helmet body (15) is arranged. Helmet (11) according to at least one of the preceding claims,
characterized in that a power consumer (25) is connected to the energy store (32). A helmet (11) according to claim 11,
characterized in that the power consumer (25) and the energy store (32) are arranged together in a recess (28) of the helmet body (15), and / or
the power consumer (25) and the energy storage (32) in separate recesses (27, 29) are arranged. A helmet (11) according to claim 11 or 12,
characterized in that the energy store (32) by means of a second cable (39) to the power consumer (25) is connected, in particular wherein the second cable (39) at least partially in a second channel (41) of the helmet body (15). A helmet (11) according to at least one of claims 11 to 13,
characterized in that the power consumer (25) is an optical or acoustic output unit.

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