DE102016109010A1 - Bicycle light emitting device and bicycle light emitting system - Google Patents

Abstract

A bicycle light emitting device (40) includes a light source (L) that is rotatable integrally with a wheel (14, 16) of a bicycle. An optical fiber element (LG) conducts light from the light source. The light guide element is rotatable integrally with the wheel.

Description

BACKGROUND

The present disclosure relates to a bicycle light emitting device and a bicycle light emitting system.

Patent Document 1 describes a bicycle light emitting device comprising a light absorbing surface and a light source. The light absorption surface is formed on the entire side surface of a wheel rim. The light source is arranged on the bicycle body at a portion that does not rotate with the wheel. Further, the light source irradiates the light absorbing surface with light. The bicycle light emitting device emits light according to the amount of light with which the light source irradiates the light absorbing surface.

DOCUMENT OF THE PRIOR ART

PATENT

• Patent Document 1: Registered Japanese Utility Model No. 3173794

SUMMARY

In the bicycle light emitting device of Patent Document 1, the area which emits light in the light absorbing surface may differ depending on the rotational speed of the wheel. Thus, the visual effect achieved by the bicycle light emitting device has a strong relation to the rotational speed of the wheel.

• (1) Nach einem ersten Aspekt der Erfindung umfasst eine Fahrrad-Lichtemittiervorrichtung eine Lichtquelle, die integral mit einem Rad eines Fahrrads drehbar ist. Ein Lichtleiterelement leitet Licht von der Lichtquelle. Das Lichtleiterelement ist integral mit dem Rad drehbar.
• (2) Nach einer bevorzugten Ausführungsform umfasst das Lichtleiterelement eine Einfallfläche, in die Licht von der Lichtquelle eintritt, eine Reflektionsfläche, die das Licht reflektiert, das in die Einfallfläche eintritt, und eine Lichtemissionsfläche, die der Reflektionsfläche gegenüberliegt.
• (3) Nach einer bevorzugten Ausführungsform erstreckt sich das Lichtleiterelement in einer vorgegebenen Richtung.
• (4) Nach einer bevorzugten Ausführungsform ist die Lichtquelle so angeordnet, dass eine optische Achse der Lichtquelle und eine Drehachse des Rades sich in verschiedene Richtungen erstrecken.
• (5) Nach einer bevorzugten Ausführungsform ist die optische Achse der Lichtquelle im Wesentlichen parallel zu einer Richtung, die zu der Drehachse des Rades orthogonal ist.
• (6) Nach einer bevorzugten Ausführungsform umfasst das Lichtleiterelement ein erstes Lichtleiterelement und ein zweites Lichtleiterelement, das von dem ersten Lichtleiterelement beabstandet ist.
• (7) Nach einer bevorzugten Ausführungsform sind das erste Leiterelement und das zweite Leiterelement in einer Umfangsrichtung des Rades angeordnet.
• (8) Nach einer bevorzugten Ausführungsform umfasst die Lichtquelle eine erste Lichtquelle und eine zweite Lichtquelle. Die erste Lichtquelle und die zweite Lichtquelle befinden sich zwischen dem ersten Lichtleiterelement und dem zweiten Lichtleiterelement.
• (9) Nach einer bevorzugten Ausführungsform befinden sich die erste Lichtquelle und die zweite Lichtquelle zwischen einer ersten Einfallfläche, die die Einfallfläche des ersten Lichtleiterelements ist, und einer zweiten Einfallfläche, die die Einfallfläche des zweiten Lichtleiterelements ist.
• (10) Nach einer bevorzugten Ausführungsform ist die erste Lichtquelle so angeordnet, dass eine optische Achse der ersten Lichtquelle die erste Einfallfläche schneidet. Die zweite Lichtquelle ist so angeordnet, dass eine optische Achse der zweiten Lichtquelle die zweite Einfallfläche schneidet.
• (11) Nach einer bevorzugten Ausführungsform umfasst die Fahrrad-Lichtemittiervorrichtung des Weiteren ein Montagesubstrat, das sich zwischen der ersten Einfallfläche und der zweiten Einfallfläche befindet. Das Montagesubstrat umfasst eine Fläche, auf der die erste Lichtquelle montiert ist, und eine weitere Fläche, auf der die zweite Lichtquelle montiert ist.
• (12) Nach einer bevorzugten Ausführungsform weist das Lichtleiterelement eine bogenförmige oder ringförmige Form auf.
• (13) Nach einer bevorzugten Ausführungsform ist die Einfallfläche an nur einem Ende in Längsrichtung des Lichtleiterelements vorgesehen.
• (14) Nach einer bevorzugten Ausführungsform nimmt die Dicke des Lichtleiterelements von dem einen Ende in Längsrichtung zu einem weiteren Ende in Längsrichtung hin ab.
• (15) Nach einer bevorzugten Ausführungsform umfasst die Reflektionsfläche ein Reflektionsmuster. Das Reflektionsmuster weist eine Dichteverteilung auf, die in einer Längsrichtung des Lichtleiterelements variiert.
• (16) Nach einer bevorzugten Ausführungsform umfasst das Lichtleiterelement in der Reflektionsfläche einen ersten Bereich, der sich an einer Seite des einen Endes in Längsrichtung befindet, einen zweiten Bereich, der sich an einer Seite des anderen Endes in Längsrichtung befindet, und einen dritten Bereich, der sich zwischen dem ersten Bereich und dem zweiten Bereich befindet. Das Reflektionsmuster in dem dritten Bereich weist eine geringere Dichteverteilung auf als das Reflektionsmuster im ersten Bereich und das Reflektionsmuster im zweiten Bereich.
• (17) Nach einer bevorzugten Ausführungsform umfasst die Fahrrad-Lichtemittiervorrichtung des Weiteren einen Steuerkreis, der in der Lage ist, die Lichtquelle mit Strom zu versorgen. Der Steuerkreis ist integral mit dem Rad drehbar.
• (18) Nach einer bevorzugten Ausführungsform umfasst die Fahrrad-Lichtemittiervorrichtung des Weiteren ein Halteelement, das in der Lage ist, das Lichtleiterelement und die Lichtquelle zu halten. Das Halteelement ist integral mit dem Rad drehbar.
• (19) Nach einer bevorzugten Ausführungsform umfasst die Fahrrad-Lichtemittiervorrichtung des Weiteren einen Draht, der die Lichtquelle mit Strom versorgt. Das Halteelement umfasst eine Drahthalterung, die den Draht hält.
• (20) Nach einer bevorzugten Ausführungsform hält die Drahthalterung den Draht in einer Umfangsrichtung des Rades. Das Lichtleiterelement ist mit der Drahthalterung so gekoppelt, dass es den Draht in einer Axialrichtung des Rades gesehen überlappt.
• (21) Nach einer bevorzugten Ausführungsform umfasst das Halteelement eine Steuerkreishalterung, die ein Substrat des Steuerkreises in einer Axialrichtung des Rades hält.
• (22) Nach einer bevorzugten Ausführungsform umfasst das Halteelement eine Radabdeckung, die scheibenförmig ist und zumindest einen Abschnitt einer Seitenfläche des Rades abdeckt.
• (23) Nach einer bevorzugten Ausführungsform umfasst die Fahrrad-Lichtemittiervorrichtung des Weiteren ein Befestigungselement, das das Lichtleiterelement am Halteelement befestigt. Das Befestigungselement deckt die Lichtquelle ab.
• (24) Nach einer bevorzugten Ausführungsform ist die Lichtquelle eine Leuchtdiode.
• (25) Nach einem zweiten Aspekt der Erfindung umfasst ein Fahrrad-Lichtemittiersystem die Fahrrad-Lichtemittiervorrichtung und einen Stromerzeuger, der Strom erzeugt, wenn sich das Rad dreht, und die Lichtquelle mit dem erzeugten Strom versorgt.
• (26) Nach einer bevorzugten Ausführungsform umfasst das Fahrrad-Lichtemittiersystem des Weiteren einen Wandler, der Wechselstrom, der von dem Stromerzeuger erzeugt wird, in Gleichstrom umwandelt, wobei der Wandler die Lichtquelle mit Gleichstrom versorgt.
• (27) Nach einem dritten Aspekt der Erfindung umfasst ein Fahrrad-Lichtemittiersystem die Fahrrad-Lichtemittiervorrichtung und eine Batterie, die die Lichtquelle mit Gleichstrom versorgt. Die Batterie ist integral mit dem Rad drehbar.

It is an object of the present disclosure to provide a bicycle light emitting device and a bicycle light emitting system whose visual effect is subtly influenced by the rotational speed of the wheel.

• (1) According to a first aspect of the invention, a bicycle light emitting device includes a light source that is rotatable integrally with a wheel of a bicycle. An optical fiber element conducts light from the light source. The light guide element is rotatable integrally with the wheel.
• (2) According to a preferred embodiment, the lightguide member includes an incident surface into which light from the light source enters, a reflection surface that reflects the light entering the incident surface, and a light emission surface that opposes the reflection surface.
• (3) According to a preferred embodiment, the optical fiber element extends in a predetermined direction.
• (4) According to a preferred embodiment, the light source is arranged so that an optical axis of the light source and a rotation axis of the wheel extend in different directions.
• (5) According to a preferred embodiment, the optical axis of the light source is substantially parallel to a direction orthogonal to the axis of rotation of the wheel.
• (6) According to a preferred embodiment, the light guide element comprises a first light guide element and a second light guide element, which is spaced from the first light guide element.
• (7) According to a preferred embodiment, the first conductor element and the second conductor element are arranged in a circumferential direction of the wheel.
• (8) According to a preferred embodiment, the light source comprises a first light source and a second light source. The first light source and the second light source are located between the first light guide element and the second light guide element.
• (9) According to a preferred embodiment, the first light source and the second light source are located between a first incident surface which is the incident surface of the first light guide element and a second incident surface which is the incident surface of the second light guide element.
• (10) According to a preferred embodiment, the first light source is arranged such that an optical axis of the first light source intersects the first incident surface. The second light source is arranged such that an optical axis of the second light source intersects the second incident surface.
• (11) According to a preferred embodiment, the bicycle light emitting device further comprises a mounting substrate located between the first incident surface and the second incident surface. The mounting substrate includes a surface on which the first light source is mounted and another surface on which the second light source is mounted.
• (12) According to a preferred embodiment, the light guide element has an arcuate or annular shape.
• (13) According to a preferred embodiment, the incident surface is provided at only one end in the longitudinal direction of the light guide element.
• (14) According to a preferred embodiment, the thickness of the light guide element decreases from the one end in the longitudinal direction to a further end in the longitudinal direction.
• (15) According to a preferred embodiment, the reflection surface comprises a reflection pattern. The reflection pattern has a density distribution that varies in a longitudinal direction of the light guide element.
• (16) According to a preferred embodiment, the light guide element in the reflection surface comprises a first region, which adjoins one another Side of one end is in the longitudinal direction, a second region which is located on one side of the other end in the longitudinal direction, and a third region which is located between the first region and the second region. The reflection pattern in the third area has a smaller density distribution than the reflection pattern in the first area and the reflection pattern in the second area.
• (17) According to a preferred embodiment, the bicycle light emitting device further comprises a control circuit capable of supplying power to the light source. The control circuit is rotatable integrally with the wheel.
• (18) According to a preferred embodiment, the bicycle light emitting device further comprises a holding member capable of holding the optical fiber element and the light source. The holding member is rotatable integrally with the wheel.
• (19) According to a preferred embodiment, the bicycle light emitting device further comprises a wire that supplies power to the light source. The holding element comprises a wire holder which holds the wire.
• (20) According to a preferred embodiment, the wire holder holds the wire in a circumferential direction of the wheel. The light guide member is coupled to the wire holder so as to overlap the wire as seen in an axial direction of the wheel.
• (21) According to a preferred embodiment, the holding member includes a control circuit holder which holds a substrate of the control circuit in an axial direction of the wheel.
• (22) According to a preferred embodiment, the retaining element comprises a wheel cover, which is disc-shaped and covers at least a portion of a side surface of the wheel.
• (23) According to a preferred embodiment, the bicycle light emitting device further comprises a fixing member fixing the light guide member to the holding member. The fastener covers the light source.
• (24) According to a preferred embodiment, the light source is a light emitting diode.
• (25) According to a second aspect of the invention, a bicycle light emitting system includes the bicycle light emitting device and a power generator that generates power when the wheel rotates and supplies the light source with the generated power.
• (26) According to a preferred embodiment, the bicycle light emitting system further comprises a converter that converts AC power generated by the power generator into DC power, the converter supplying DC power to the light source.
• (27) According to a third aspect of the invention, a bicycle light emitting system includes the bicycle light emitting device and a battery that supplies DC power to the light source. The battery is rotatable integrally with the wheel.

The visual effect of the bicycle light emitting device and the bicycle light emitting system is subtly influenced by the rotational speed of the wheel.

BRIEF DESCRIPTION OF THE DRAWINGS

The object of the present disclosure, together with its objects and advantages, may best be understood by reference to the following description of the presently preferred embodiments, taken in conjunction with the accompanying drawings, in which:

1 Fig. 10 is a side view of a bicycle including an embodiment of a bicycle light emitting system;

2 a block diagram is showing the electrical structure of the bicycle Lichtemittiersystems 1 shows;

3 an exploded perspective view, which is a front wheel and a light emitting unit of a bicycle Lichtemittiervorrichtung 1 shows;

4 is a front view of a first wheel cover;

5 is a rear view of the first wheel cover;

6 an exploded perspective view of the first wheel cover 3 and an element coupled to the first wheel cover;

7 is a front view of a light emitting unit, from which a hub dynamo, a translucent cover and a fastener of the in 3 omitted light emitting unit are omitted;

8th an exploded perspective view of a light guide element, a reflection foil and a support member;

9 a bottom view of the light guide element 8th is;

10 an exploded perspective view of the first wheel cover and a first light source unit;

11 is a side view showing the positional relationship of the first light source unit, the first light guide element and the second light guide element;

12 a cross-sectional view of the light emitting unit 3 is;

13 a partially enlarged view of the in 12 is shown light emitting unit;

14 is a rear view of the first wheel cover;

15 is a front view of the first wheel cover;

16 a rear view of the second wheel cover is;

17 is a front view of the second wheel cover;

18 a cross-sectional view of in 3 shown hub dynamo is;

19 an exploded perspective view of an in 18 is shown connection unit;

20 a side view of a first terminal is in 19 will be shown;

21 a side view of a second terminal is in 19 will be shown;

22 is an exploded perspective view of an armature of the hub dynamo and a limiting mechanism, which in 18 to be shown;

23 FIG. 4 is a perspective view showing a first retainer plate and a second retainer plate of the first restricting mechanism exiting to the armature. FIG 22 is coupled;

24 FIG. 4 is a perspective view showing a lock nut, which is also made to the first holding plate and the second holding plate 23 is coupled;

25 FIG. 12 is a perspective view showing a bearing holding member provided to the first restricting mechanism. FIG 24 is coupled;

26 an enlarged view of the first bearing and the second bearing is in 18 to be shown;

27 a plan view of the bracket 18 seen in the axial direction;

28 Fig. 11 is a front view showing a modified example of the light emitting unit of the bicycle light emitting device, from which the hub dynamo, the translucent cover and the fixing member are omitted;

29 Fig. 11 is a front view showing a modified example of the light emitting unit of the bicycle light emitting device, from which the hub dynamo, the translucent cover and the fixing member are omitted;

30 Fig. 11 is a front view showing a modified example of the light emitting unit of the bicycle light emitting device, from which the hub dynamo, the translucent cover and the fixing member are omitted; and

31 an enlarged view of a first bearing and a hub dynamo in a modified example.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

It will now be the construction of a bicycle 10 comprising a bicycle light emitting system with reference to FIGS 1 and 2 described.

As in 1 shown, includes the bike 10 a body 12 , a front wheel 14 and a rear wheel 16 , The light emitting system of the bicycle 10 includes a light emitting device 40 and a power supply device 170 , The light emitting device 40 is an example of a bicycle light emitting device, the light from the two side surfaces respectively of the front wheel 14 and the rear wheel 16 emitted. The power supply device 170 supplies a light source L (see 2 ) of the light emitting device 40 with electricity. A tire 18 is each to the front wheel 14 and the rear wheel 16 coupled.

The body 12 includes a main frame 20 , a front fork 22 and a handlebar 24 , The front fork 22 and the handlebars 24 are each on the main frame 20 coupled.

The front wheel 14 includes a rim 26 (please refer 3 ) on which the tire 18 is attached, a hub dynamo 180 in a rotatable manner to the front fork 22 coupled, and spokes 28 (please refer 3 ), which is the hub dynamo 180 and the rim 26 couple together. The hub dynamo 180 includes a power generator for generating alternating current when the front wheel 14 rotates.

The rear wheel 16 includes a hub 30 , which in a rotatable manner to the main frame 20 coupled to a rim (not shown) to which the tire 18 attached, and spokes (not shown), which is the hub 30 and couple the rim together.

The light emitting device 40 becomes integral with the front wheel 14 and the rear wheel 16 turned. The light emitting device 40 includes a light emitting unit 42A , the light from the two side surfaces of the front wheel 14 emitted, and a light emitting unit 42B , the light from the two side surfaces of the rear wheel 16 emitted.

The light emitting unit 42A is at the front wheel 14 coupled to the rim 26 and all of the plurality of spokes 28 of the front wheel 14 from both sides. The light emitting unit 42B is to the rear wheel 16 coupled to the rim and all of the spokes of the rear wheel 16 from both sides.

The power supply device 170 includes a controller 44 that supplies the power to the hub dynamo 180 of the front wheel 14 and the power supply from the hub dynamo 180 to each of the light emitting units 42A . 42B controls.

As in 2 shown connects the power supply device 170 the hub dynamo 180 , the control 44 and the light emitting units 42A . 42B with each other electrically. Thus, the alternating current passing through the hub dynamo 180 is generated, the light emitting units 42A . 42B through the controller 44 fed.

The light emitting unit 42A includes a first light source unit 48 , a second light source unit 50 a third light source unit 52 , a fourth light source unit 54 and a control circuit 56 , The drive circuit 56 controls the power supply from the controller 44 to the first light source unit 48 , Furthermore, the control circuit includes 56 a current limiter (not shown) that controls the current of the first light source unit 48 is supplied so that the current is less than or equal to a threshold. The control circuit 56 is covered by a waterproof coating.

The first light source unit 48 and the second light source unit 50 are on a side surface of the front wheel 14 arranged (see 3 ). The third light source unit 52 and the fourth light source unit 54 are on the other side surface of the front wheel 14 arranged.

The first light source unit 48 includes a first light source 58 , a second light source 60 and a first mounting substrate 62 on which the first light source 58 and the second light source 60 are mounted. The second light source unit 50 includes a third light source 64 , a fourth light source 66 and a second mounting substrate 68 on which the third light source 64 and the fourth light source 66 are mounted. The third light source unit 52 includes a first light source 70 , a second light source 72 and a first mounting substrate 74 on which the first light source 70 and the second light source 72 are mounted. The fourth light source unit 54 includes a third light source 76 , a fourth light source 78 and a second mounting substrate 80 on which the third light source 76 and the fourth light source 78 are mounted. Each of the light source units 48 . 50 . 52 . 54 is covered by a waterproof coating. In this way, the bicycle light emitting device comprises 40 a light source L that integrates with the front wheel 14 rotates. The light source L includes the first light source unit 48 , the second light source unit 50 , the third light source unit 52 , and the fourth light source unit 54 , Thus, the light source L includes the first light source 58 and the second light source 60 , Furthermore, the light source L comprises the first light source 70 and the second light source 72 , Further, the light source L includes the third light source 64 serving as a first light source and the fourth light source 66 which serves as the second light source. The light source L also includes the third light source 76 , which serves as the first light source, and the fourth light source 78 which serves as the second light source. As described above, the light emitting device is 40 integral with the front wheel 14 rotatable, and includes a control circuit 56 , which supplies the light source L with electricity.

Each of the light sources 58 . 60 . 64 . 66 . 70 . 72 . 76 . 78 is for example a light emitting diode. Every light source 58 . 60 . 64 . 66 . 70 . 72 . 76 . 78 may be an EL lamp, a halogen lamp, an incandescent lamp, a neon lamp and the like.

As in 2 shown, the light emitting unit 42B a structure that the light emitting unit 42A is similar, and includes the first light source unit 48 , the second light source unit 50 , the third light source unit 52 , the fourth light source unit 54 and the control circuit 56 ,

The control 44 includes a transducer 82 , a capacitor 84 and a control unit 86 , The converter 82 Converts alternating current through the hub dynamo 180 is generated, in DC. The capacitor 84 serves as an example of a power storage unit that controls the power of the converter 82 stores. The control unit 86 controls the supply of power from the capacitor 84 to the light emitting units 42A . 42B , An example of the capacitor 84 may be an electric double layer capacitor. The power storage unit may be a rechargeable battery, such as a lithium-ion battery.

The power supply device 170 includes a wire group 46A , which serves as an example of wires that each of the light sources 58 . 60 . 64 . 66 power, and a wire group 46B , which serves as an example of wires that each of the light sources 70 . 72 . 76 . 78 supply electricity. The control 44 is through the wire group 46A electrically with the light emitting unit 42A connected. Further, the controller 44 through the wire group 46B electrically with the light emitting unit 42B connected.

The wire group 46A includes a first wire 88 , a second wire 90 , a third wire 92 , a fourth wire 94 , a fifth wire 96 , a sixth wire 98 and a seventh wire 100 , The first wire 88 and the seventh wire 100 connect the controller 44 and the control circuit 56 the light emitting unit 42A with each other electrically. The second wire 90 connects the control circuit 56 and the first light source unit 48 electrically with each other. The third wire 92 connects the first light source unit 48 and the second light source unit 50 electrically with each other. The fourth wire 94 connects the second light source unit 50 and the third light source unit 52 electrically with each other. The fifth wire 96 connects the third light source unit 52 and the fourth light source unit 54 electrically with each other. The sixth wire 98 connects the fourth light source unit 54 and the control circuit 56 electrically with each other.

The wire group 46B includes a first wire 102 , a second wire 104 , a third wire 106 , a fourth wire 108 , a fifth wire 110 , a sixth wire 112 and a seventh wire 114 , As in 2 shown is the connection of the controller 44 and the control circuit 56 the light emitting unit 42B with the wire group 46B similar to the connection of the light source units 48 . 50 . 52 . 54 and the control circuit 56 the light emitting unit 42B with the wire group 46A ,

The operation of the light emitting device 40 will now be described.

The hub dynamo 180 generates alternating current when the front wheel 14 rotates. The alternating current of the hub dynamo 180 becomes the controller 44 fed and through the converter 82 converted into direct current. The direct current becomes the capacitor 84 and the control circuit 56 the light emitting units 42A . 42B fed. In this case, the capacitor becomes 84 charged with the direct current. The control circuit 56 the light emitting units 42A . 42B carries the direct current in the order of the first light source unit 48 , second light source unit 50 , third light source unit 52 and fourth light source unit 54 the light emitting units 42A . 42B to. This emits light from the light source 58 . 60 . 64 . 66 . 70 . 72 . 76 . 78 , In this way, the generator produces the hub dynamo 180 Electricity when the front wheel 14 turns, and supplies each of the light sources 58 . 60 . 64 . 66 . 70 . 72 . 76 . 78 with the electricity generated. The converter 82 converts the alternating current generated by the generator of the hub dynamo 180 was generated, converted into direct current and supplies each of the light sources 58 . 60 . 64 . 66 . 70 . 72 . 76 . 78 with the direct current.

If the front wheel 14 stops turning and generating alternating current with the hub dynamo 180 stops, no more AC power from the hub dynamo 180 the controller 44 fed. The capacitor 84 the controller 44 is charged with DC, and the DC becomes the control circuit 56 each of the light emitting units 42A . 42B fed. Thus, the light emission of the light sources moves 58 . 60 . 64 . 66 . 70 . 72 . 76 . 78 each for a fixed period of time to emit light while the capacitor 84 DC supplies after the front wheel 14 stops turning.

The structure of the light emitting unit 42A will now be detailed with reference to the 3 to 17 described. The structure of the light emitting unit 42B is the structure of the light emitting unit 42A similar, and is therefore not described.

As in 3 shown includes the light emitting unit 42A a first wheel cover 116A serving as an example of a holding member having the side surface on one side of the front wheel 14 covering, and a second wheel cover 116B serving as an example of a holding member, which is the side surface on the other side of the front wheel 14 covers. The wheel covers 116A . 116B are each integral with the front wheel 14 turned.

The first wheel cover 116A and the second wheel cover 116B point with respect to the front wheel 14 a symmetrical shape. Each of the wheel covers 116A . 116B is formed of a resin material. Each of the wheel covers 116A . 116B is disc-shaped and covers at least a portion of the front wheel 14 from. The first wheel cover 116A and the second wheel cover 116B are together with four bolts 118 and four nuts 120 attached.

In the following description, the same reference numerals will be used for corresponding elements of the first wheel cover 116A and the second wheel cover 116B used. Further, the structure of the second wheel cover 116B not described.

The first wheel cover 116A includes an annular cover body 122 , a hub fitting portion 124 extending from the inner circumference of the cover body 122 extends inwardly, and a rim coupling portion 126 extending from an outer periphery of the cover body 122 extends to the outside.

The cover body 122 covers the spokes 28 the front wheel 14 from. The cover body 122 is inclined from the inner periphery to the outer periphery, so that the cover body 122 the axially middle part of the front wheel 14 approaches.

The hub fitting section 124 includes a cylinder 124A and an annular flange 124B extending from the inner circumference of the distal end of the cylinder 124A extends inwards. The hub dynamo 180 is in the hub fitting section 124 fitted.

The rim coupling section 126 has a plane corresponding to the axial direction of the front wheel 14 is orthogonal. As in 4 shown has the rim coupling portion 126 a front surface having a holding portion 128 includes, which is an annular groove.

Four coupling holes 126A , which are spaced apart in the circumferential direction, extend through the rim coupling portion 126 in the axial direction. Every coupling hole 126A includes two holes. One of the two holes is located on the radially inner side of the holding portion 128 , The other of the two holes is located on the radially outer side of the holding portion 128 , The coupling holes 126A are arranged at intervals of 90 °.

The rim coupling section 126 includes a first substrate holding section 126B and a second substrate holding section 126C which are spaced in the circumferential direction. The first substrate holding section 126B and the second substrate holding section 126C are at the same circumferential positions as two of the four coupling holes 126A , Each of the substrate holding sections 126B . 126C is a recess and traverses the holding section 128 ,

The holding section 128 includes a first insertion hole 126D and a second insertion hole 126E located on opposite sides of the first substrate holding section 126B in the circumferential direction. The holding section 128 also includes a third insertion hole 126F and a fourth insertion hole 126G located on opposite sides of the second substrate holding section 126C in the circumferential direction.

As in 5 is shown includes the rear surface of the cover body 122 four plug-in sections 130 and a carrying wall 134 , A bolt 118 and a mother 120 (please refer 3 ) are in each insertion section 130 plugged in. The carrying wall 134 serves as an example of a control circuit holder which is a control substrate 132 (please refer 12 ) that carries the control circuit 56 (please refer 2 ). Each insertion section 130 is a tube extending in the axial direction from the cover body 122 extends. The carrying wall 134 is at the generally same position as the first substrate holding section 126B formed in the circumferential direction. The carrying wall 134 is a plate extending in the axial direction from the cover body 122 extends.

The light emitting device 40 comprises a light guide element LG which guides light from the light source L. The light guide element LG is integral with the front wheel 14 rotatable. The first wheel cover 116A , which is an example of a holding member, is capable of holding the light guide member LG and the light source L. As in 6 shown in an example holds the holding section 128 of the rim coupling section 126 the first light source unit 48 , the second light source unit 50 , a first optical fiber element 136 , a second optical fiber element 138 , a third optical fiber element 140 and a fourth optical fiber element 142 , Furthermore, the holding section stops 128 a first reflection foil 144 , a second reflection foil 146 , a first support element 148 and a second support member 150 , The light guide element LG comprises the first light guide element 136 , the second optical fiber element 138 , the third optical fiber element 140 and the fourth optical fiber element 142 ,

As in 7 shown, directs the first light guide element 136 Light from the first light source 58 , the second optical fiber element 138 conducts light from the second light source 60 , the third optical fiber element 140 conducts light from the third light source 64 , and the fourth optical fiber element 142 conducts light from the fourth light source 66 ,

As in 6 Shown is the holding section 128 a first translucent cover 152 , a second translucent cover 154 , a third translucent cover 156 and a fourth translucent cover 158 ,

The light guide elements 136 . 138 . 140 . 142 and the translucent covers 152 . 154 . 156 . 158 are formed of a translucent resin material. Preferably, the translucent covers 152 . 154 . 156 . 158 formed of a transparent and colorless resin material. The translucent covers 152 . 154 . 156 . 158 can be omitted. The light guide elements 136 . 138 . 140 . 142 and the translucent covers 152 . 154 . 156 . 158 are in the circumferential direction of the front wheel 14 arranged (see 3 ). The light guide elements 136 . 138 . 140 . 142 run in a given direction. One Example of the given direction is the circumferential direction.

As in 6 shown have the light guide elements 136 . 138 . 140 . 142 and the translucent covers 152 . 154 . 156 . 158 seen in the axial direction in each case an arcuate shape. The light guide elements 136 . 138 . 140 . 142 each have the same size and shape. Furthermore, the translucent covers 152 . 154 . 156 . 158 each the same size and shape. The translucent covers 152 . 154 . 156 . 158 are each seen in the circumferential direction U-shaped. That is, the translucent covers 152 . 154 . 156 . 158 each have a U-shaped cross-section. The reflection slides 144 . 146 and the carrying elements 148 . 150 each have a semicircular shape as viewed in the axial direction.

The translucent covers 152 . 154 . 156 . 158 are arranged in the circumferential direction to form a ring. The first translucent cover 152 and the second translucent cover 154 cover the first light source unit 48 from. The third translucent cover 156 and the fourth translucent cover 158 cover the second light source unit 50 from. Therefore, the light source unit is 48 adjacent to the adjacent end faces of the first translucent cover 152 and the second translucent cover 154 arranged, and the light source unit 50 is adjacent to the adjacent end faces of the third translucent cover 156 and the fourth translucent cover 158 arranged.

A first fastener 160 , a second fastener 162 , a third fastener 164 and a fourth fastening element 166 are each with the four coupling holes 126A of the rim coupling section 126 coupled.

The fasteners 160 . 162 . 164 . 166 each include two hooks 160A . 162A . 164A . 166A , The two hooks 160A . 162A . 164A . 166A are in the two holes of the corresponding coupling holes 126A fitted to the fasteners 160 . 162 . 164 . 166 at four points to the rim coupling section 126 to pair. The first fastening element 160 covers the limit of the first translucent cover 152 and the second translucent cover 154 from. The second fastening element 162 covers the border of the third translucent cover 156 and the fourth translucent cover 158 from. The third fastening element 164 covers the limit of the first translucent cover 152 and the third translucent cover 156 from. The fourth fastening element 166 covers the border of the second translucent cover 154 and the fourth translucent cover 158 from. The fasteners 160 . 162 . 164 . 166 attach the translucent covers 152 . 154 . 156 . 158 at the holding section 128 , This fixes the light guide elements 136 . 138 . 140 . 142 at the first wheel cover 116A , Thus, the light emitting device comprises 40 a fastener B, which covers the light source L and the light guide element LG on the holding element (wheel covers 116A . 116B ) fixed. The fastening element B comprises the first fastening element 160 and the second fastening element 162 ,

The first mounting substrate 62 is at the first substrate holding section 126B of the rim coupling section 126 coupled. The second mounting substrate 68 is at the second substrate holding section 126C coupled.

As in 7 is shown is the second optical fiber element 138 from the first light guide element 136 spaced. The fourth light guide element 142 is from the third optical fiber element 140 spaced.

The first mounting substrate 62 is between the first light guide element 136 and the second optical fiber element 138 arranged in the circumferential direction. The first light source 58 is on a main surface 62A of the first mounting substrate 62 mounted, and the second light source 60 is on the other main surface 62B of the first mounting substrate 62 assembled. The second mounting substrate 68 is between the third light guide element 140 and the fourth optical fiber element 142 arranged in the circumferential direction. The third light source 64 is on a main surface 68A of the second mounting substrate 68 mounted, and the fourth light source 66 is on the other main surface 68B of the second mounting substrate 68 assembled. The first mounting substrate 62 is located on the border of the first translucent cover 152 and the second translucent cover 154 (both in 6 shown), and the second mounting substrate 68 is located at the boundary portion of the third translucent cover 156 and the fourth cover 158 (both in 6 shown). A mounting substrate may be on each of the first to fourth light sources 58 . 60 . 64 . 66 be mounted.

As in 8th is shown, the first light guide element 136 through the first support element 148 carried, and the second light guide element 138 is through the second support element 150 carried. The first reflection foil 144 is on a support surface 148A of the first support element 148 coupled, and the second reflection foil 146 is on a support surface 150A of the second support element 150 coupled. Although not in 8th is shown, the third optical fiber element 140 through the second carrying member 150 carried, and the fourth light guide element 142 is through the first support element 148 carried.

The light guide element LG comprises an incident surface LG1, a reflection surface LG2 and a light emission surface LG3. Light from the light source L enters the incident surface LG1. The reflection surface LG2 reflects the light entering the incident surface LG1. The light emission surface LG3 is opposite to the reflection surface LG2. As in 8th For example, shown includes the first light guide element 136 serving as an example of the light guide member LG, a first incident surface 136A , a first reflection surface 136B and a first light emission surface 136C , The first incidence area 136A is the incident surface LG1, in which the light from the first light source 58 (please refer 7 ) entry. The first reflection surface 136B is the reflection surface LG2, which reflects the light on the first incident surface 136A meets. The first light emission surface 136C is the light emission surface LG3, that of the first reflection surface 136B is facing. The first incidence area 136A is formed by an end face in the circumferential direction of the first optical fiber element 136 educated. As in 8th shown is the first incidence area 136A at only one end in the circumferential direction, or the longitudinal direction, of the first optical fiber element 136 educated. The first reflection surface 136B is inclined to look at the first light emission surface 136C from the first incidence area 136A to the other end face in the circumferential direction of the first light guide element 136 approach. The first light emission surface 136C is a plane that is orthogonal to the axial direction. Thus, the thickness of the first optical fiber element becomes 136 from one end to the other end in the circumferential direction, or the longitudinal direction, of the first optical fiber element 136 reduced.

As in 9 is shown comprises the first reflection surface 136B a reflection pattern 136D , The reflection pattern 136D has a density distribution in the circumferential direction, or the longitudinal direction, of the first light guide element 136 varied. The reflection pattern 136D includes white dots on the first reflection surface 136B are printed. The density of the reflection pattern 136D is the number of points per unit area.

The first reflection surface 136B of the first light guide element 136 includes a first region R1 located on a peripheral side of the first optical fiber element 136 located, a second region R2, which is located on the other peripheral side of the first light guide element 136 and a third region R3 extending between the first region R1 and the second region R2 in the first optical fiber element 136 located. The density of the reflection pattern 136D in the third region R3 is less than the density of the reflection pattern 136D in the first region R1 and the density of the reflection pattern 136D in the second area R2. As in 9 to see is the reflection pattern 136D designed so that the density of the reflection pattern 136D gradually from the two circumferential ends to the circumferentially central portion of the first optical fiber element 136 decreases. The reflection pattern 136D may be pits and ridges formed in the reflection surface LG2, or a reflection sheet applied on the reflection surface LG2. The reflection surface LG2 needs to reflect only light from the light source L to the light emission surface LG3.

As in 8th shown comprises the second light guide element 138 , which is an example of the light guide element LG, a second incident surface 138A , a second reflection surface 138B and a second light emission surface 138C , Light from the second light source 60 (please refer 7 ) enters the second area of incidence 138A one. The second reflection surface 138B reflects the light that enters the second incident surface 138A entry. The second light emission surface 138C lies the second reflection surface 138B across from. The second incident surface 138A is through an end in the circumferential direction of the second optical fiber element 138 educated. As in 8th shown is the second incident surface 138A at only one end in the circumferential direction, or the longitudinal direction, of the second optical fiber element 138 educated. The second reflection surface 138B is inclined to look at the second light emission surface 138C from the second incident surface 138A to the other end face in the circumferential direction of the second light guide element 138 approach. The second light emission surface 138C is a plane that is orthogonal to the axial direction. Thus, the thickness of the second optical fiber element becomes 138 from one end to the other end in the circumferential direction, or the longitudinal direction, of the second optical fiber element 138 reduced. The second reflection surface 138B has a reflection pattern that is in its shape the reflection pattern 136D the first reflection surface 136B , in the 9 is shown is similar.

The first carrying element 148 includes a support surface 148A and a placement area 148B that the carrying surface 148A is opposite. The arrangement area 148B is a plane that is orthogonal to the axial direction. The carrying surface 148A is inclined to move away from the placement surface 148B from one end of the first support member 148 for circumferentially central portion of the first support member 148 to remove. Thus, the thickness of the first support member 148 from one end of the first support member 148 for circumferentially central portion of the first support member 148 increased. Although not in 8th is shown, the thickness of the first support member 148 from the circumferentially central portion of the first support member 148 to the other end of the first support member 148 decreased.

The second carrying element 150 includes a support surface 150A and a placement area 150B that the carrying surface 150A is opposite. The carrying surface 150A and the placement area 150B have a structure on which the support surface 148A and the placement surface 148B of the first support element 148 is similar. The thickness of the first reflection foil 144 and the thickness of the second reflection film 146 are uniform in the circumferential direction and equal to each other.

As in 10 shown is the first mounting substrate 62 in the first substrate holding section 126B arranged so that the main surfaces 62A . 62B parallel to the axial direction. As in 11 shown are thus the main surfaces 62A . 62B each of the first incident surface 136A and the second incident surface 138A facing. The first light source 58 and the second light source 60 are between the first incidence area 136A and the second incident surface 138A arranged. The first mounting substrate 62 is between the first incidence area 136A and the second incident surface 138A arranged.

The light source L may be fixed so that the optical axis is in a direction different from the direction in which the rotation axis of the front wheel 14 runs (see 3 ). The optical axis of the light source L is substantially parallel to a direction parallel to the axis of rotation of the front wheel 14 is orthogonal. As in 11 shown is the first light source 58 arranged such that the optical axis (single dashed line) to the first incident surface 136A is orthogonal, and the second light source 60 is arranged such that the optical axis (single dashed line) to the second incident surface 138A is orthogonal. The optical axis of the first light source 58 is to the first incidence area 136A orthogonal, and the optical axis of the second light source 60 is to the second incident surface 138A orthogonal.

As in 6 shown have the third optical fiber element 140 and the fourth optical fiber element 142 the same shape as the first light guide element 136 and the second optical fiber element 138 , As in 7 is shown, the positional relationship of the third optical fiber element 140 and the fourth optical fiber element 142 relative to the third light source 64 , the fourth light source 66 and the second Monday submission 68 similar to the positional relationship of the first optical fiber element 136 and the second optical fiber element 138 relative to the first light source 58 , the second light source 60 and the first assembly council 62 ,

As in 12 is shown, when the first wheel cover 116A and the second wheel cover 116B are coupled to each other, the control substrate 132 between the cover body 122 the first wheel cover 116A and the cover body 122 the second wheel cover 116B , Thus, the control substrate 132 in the internal area between the first wheel cover 116A and the second wheel cover 116B added. The control substrate 132 is held so that it is integral with the front wheel 14 is rotatable. The control substrate 132 is for example on the carrying wall 134 the first wheel cover 116A fixed by a screw (not shown). The carrying wall 134 serves as an example of a control circuit holder containing the control substrate 132 of the control circuit 56 parallel to the axial direction of the front wheel 14 (please refer 3 ) holds.

13 shows the fourth light guide element 142 , the second reflection foil 146 , the second carrying element 150 , the fourth translucent cover 158 and the third wire 92 passing through the holding section 128 being held.

As in 13 shown, the holding section comprises 128 a first holding section 128A , a second holding section 128B and a third holding section 128C , The first holding section 128A , the second holding section 128B and the third holding section 128C are in this order from the front to the rear of the first wheel cover 116A trained. The radial width of the first holding portion 128A , the radial width of the second holding portion 128B and the radial width of the third holding portion 128C take off in this order.

The fourth translucent cover 158 is in the first holding section 128A fitted. The fourth light guide element 142 , the second reflection foil 146 and the second support member 150 are in the first holding section 128A and the second holding portion 128B arranged. As in 13 is the fourth optical fiber element 142 that in the fourth translucent cover 158 is arranged through the fourth translucent cover 158 covered in the axial direction and the radial direction. A portion of the fourth optical fiber element 142 at one end in the circumferential direction of the fourth optical fiber element 142 sticking out of the fourth translucent cover 158 to the second holding section 128B out. An circumferentially central portion of the second support member 150 is in the fourth translucent cover 158 arranged. The third wire 92 is in the third holding section 128C arranged. The other optical fiber elements, reflective sheets, support members, translucent covers, and wire groups are passed through the support portion in the same manner 128 held. On this way includes the first wheel cover 116A the first holding section 128C acting as a wire holder that holds the wire. As in 13 shown, the light guide element to the first wheel cover 116A be coupled so that it is the wire from the axial direction of the front wheel 14 (please refer 3 ) overlaps. The wire holder can hold the wire in the circumferential direction of the front wheel 14 ( 3 ) hold.

The wires of the wire group 46A in each of the wheel covers 116A . 116B will now be described.

As in 14 shown are the first wire 88 and the seventh wire 100 that with the controller 44 (please refer 2 ) are connected to the control substrate 132 through the hub dynamo 180 and the hub fitting portion 124 on the back of the first wheel cover 116A connected. The first wire 88 is with a main surface 132A of the control substrate 132 connected, and the seventh wire 100 is with the other major surface 132B of the control substrate 132 connected. Furthermore, it is a main area 132A of the control substrate 132 with the second wire 90 connected, and the other main surface 132B of the control substrate 132 is with the sixth wire 98 connected. The second wire 90 is in the first insertion hole 126D plugged in.

As in 15 shown, the second wire extends 90 from the first insertion hole 126D in the holding section 128 (third stop section 128C ) on the front of the first wheel cover 116A , The second wire 90 is with a main surface 62A of the first mounting substrate 62 connected. The other main area 62B of the first mounting substrate 62 is with the third wire 92 connected. As in 15 shown is the third wire 92 in the semicircular area of the third holding portion 128C laid, seen in the axial direction, and is with the main surface 68B of the second mounting substrate 68 connected. The main area 68A of the second mounting substrate 68 is with the fourth wire 94 connected. The fourth wire 94 is in the third insertion hole 126F plugged in and extends through the back of the first wheel cover 116A , as in 14 to see, to the rear surface of the second wheel cover 116B (please refer 16 ).

As in 16 shown is the fourth wire 94 in the first insertion hole 126D from the back of the second wheel cover 116B plugged in.

As in 17 shown, the fourth wire extends 94 from the first insertion hole 126D to the front of the second wheel cover 116B , The fourth wire 94 is with a main surface 74A of the first mounting substrate 74 the third light source unit 52 connected. The other main area 74B of the first mounting substrate 74 is with the fifth wire 96 connected. As in 17 shown is the fifth wire 96 in the semicircular area of the third holding portion 128C the second wheel cover 116B laid and with the main surface 80B of the second mounting substrate 80 in the fourth light source unit 54 connected. The main area 80A of the second mounting substrate 80 is with the sixth wire 98 connected. The sixth wire 98 is in the third insertion hole 126F plugged in and extends through the back of the second wheel cover 116B , as in 17 to see, to the rear side of the first wheel cover 116B , as in 14 shown. As in 14 shown is the sixth wire 98 with the main surface 132B of the control substrate 132 connected.

The structure of the hub dynamo 180 for supplying the light emitting unit 42A with electricity will now be detailed with reference to the 18 to 27 described.

The hub dynamo 180 includes a hub shell 182 attached to the spokes 28 (please refer 3 ) of the front wheel 14 is coupled and integral with the front wheel 14 is turned. A hub shaft 184 at the front fork 22 (please refer 1 ) is fixed in the hub shell 182 plugged in. The hub shell 182 is worn so that it is relative to the hub shaft 184 is rotatable. The hub shaft 184 extends in the axial direction. The hub shaft 184 includes a wire receiving portion 186 which has the shape of a groove shape and extending from one axial end to the other axial end of the hub shaft 184 extends. The hub shaft 184 includes a first threaded portion 188 and a second threaded portion 190 which are spaced in the axial direction.

A first camp 192 , a second camp 194 and a third camp 196 that the hub shell 182 so wear it relative to the hub shaft 184 is rotatable, are between the hub shell 182 and the hub shaft 184 arranged. Each of the bearings 192 . 194 . 196 is a ball bearing. Each of the bearings 192 . 194 . 196 may be another type of bearing, such as a roller bearing instead of a ball bearing, as long as it is a bearing that rolls. The first camp 192 and the second camp 194 are at one axial end of the hub shell 182 arranged, and the third camp 196 is at the other axial end of the hub shell 182 arranged. As in 18 shown are the first camp 192 and the second camp 194 spaced in the axial direction.

A first sealing element 198 and a second sealing element 200 are between the hub shell 182 and the hub shaft 184 attached. The first sealing element 198 seals the gap at one end of the hub shell 182 and the hub shaft 184 from. The second sealing element 200 seals the gap at the other end of the hub shell 182 and the hub shaft 184 from.

The hub shell 182 is tubular and has a sealed hollow area. Furthermore, the hub shell includes 182 a housing 202 and a holder 204 ,

The housing 202 is formed, for example, of a metal material. The housing 202 (Hub housing 182 ) comprises a cylindrical portion 206 extending in the axial direction and a side wall 208 located at one axial end of the cylindrical section 206 located. The holder 204 is at an axial end of the cylindrical portion 206 coupled. The holder 204 defines a first side portion having a first opening 206A closes, located on one axial side of the cylindrical section 206 located. The side wall 208 defines a second side portion having a second opening 206B closes, located on the other axial side of the cylindrical section 206 located. In 18 become the cylindrical section 206 and the side wall 208 formed by the same element. However, the cylindrical section can 206 and the side wall 208 be separately formed elements which are coupled together by bolts, welding or an adhesive. The housing 202 may be formed of a resin material.

The side wall 208 that is the second side portion includes a second bearing seat 208A , which interacts with the hub shaft 184 is trained. The second bearing seat 208A located between the axial end of the hub shell 182 and the corresponding axial end of the hub shaft 184 , The third camp 196 is at least partially through the second bearing seat 208A carried. The second sealing element 200 is at the second bearing seat 208A coupled.

The third camp 196 includes an inner ring 210 at the second threaded portion 190 is attached, an outer ring 212 coming from one axial end of the inner ring 210 is spaced, and rolling elements 214 between the inner ring 210 and the outer ring 212 are arranged.

A generator is in the hub shell 182 arranged. More precisely, they are an anchor 216 , four permanent magnets 218 and a cylindrical, rear yoke 220 in the case 202 housed the generator in the hub dynamo 180 to build. The four permanent magnets 218 are laid so that the N pole and the S pole are alternately arranged in the circumferential direction. The permanent magnet 218 may be a single annular permanent magnet. Alternatively, the permanent magnet 218 two, three, or five or more permanent magnets arranged in the circumferential direction.

The anchor 216 is an anchor of claw pole type. The anchor 216 comprises a cylindrical coil carrier 222 and a coil 224 By winding conductive wire around the bobbin 222 be formed. The anchor 216 includes first claws 226 extending from one axial end to the other axial end of the bobbin 222 and second claws 228 extending from the other axial end to an axial end of the bobbin 222 run out. The first claws 226 and the second claws 228 , which are magnetic bodies, are with the coil carrier 222 coupled so that they are arranged alternately in the circumferential direction.

The anchor 216 is between a first limiting mechanism 230 and a second limiting mechanism 232 held. This positions the anchor 216 relative to the hub shaft 184 and limits axial movement of the armature 216 ,

The first limiting mechanism 230 includes a first retaining plate 234 that has an axial end of the bobbin 222 contacted, a second holding plate 236 attached to the first retaining plate 234 is fixed, and a locking nut 238 holding the retaining plates 234 . 236 between the locking nut 238 and the coil carrier 222 attached.

The second limiting mechanism 232 includes a first retaining plate 240 , which is an annular plate, the other axial end of the bobbin 222 contacted, and a locking nut 242 holding the retaining plates 240 on the bobbin 222 attached. The locking nut 242 is at the hub shaft 184 fixed.

The back yoke 220 which is a magnetic body is at the cylindrical portion 206 of the housing 202 fixed. The four arc-shaped permanent magnets 218 are on the inner peripheral surface of the rear yoke 220 fixed. The four permanent magnets 218 are arranged in the circumferential direction and from the first jaws 226 and the second claw 228 spaced.

The holder 204 For example, it is formed of a metal material such as aluminum. The holder 204 serving as an example of the first side section includes a first bearing seat 244 , which interacts with the hub shaft 184 is trained. The first camp seat 244 is between the one end of the hub shell 182 and one end of the hub shaft 184 arranged. As in 18 be shown, be the first camp 192 and the second camp 194 at least partially through the first bearing seat 244 carried. The first sealing element 198 is at the first camp seat 244 coupled. The holder 204 may be formed of a resin material.

The first camp seat 244 includes a first seat portion 244A who is at the first camp 192 coupled, and a second seat portion 246 who sent to the second camp 194 is coupled. The first seat section 244A and the second seat portion 246 are arranged adjacent to each other in the axial direction.

The first camp 192 includes an inner ring 248 indirectly through the hub shaft 184 is worn, an outer ring 250 that of the inner ring 248 is spaced and indirectly through the first seat portion 244A is worn, and rolling elements 252 between the inner ring 248 and the outer ring 250 are arranged. The inner ring 248 , the outer ring 250 and the rolling elements 252 are made of metal.

The second camp 194 includes an inner ring 254 that is at the hub shaft 184 is fixed, an outer ring 256 that of the inner ring 254 spaced and the second seat portion 246 coupled, and rolling elements 258 between the inner ring 254 and the outer ring 256 are arranged. The inner ring 254 , the outer ring 256 and the rolling elements 258 are made of metal.

A first limiting element 260 and a second limiting element 262 are on the two axial sides of the inner ring 254 in the hub shaft 184 fixed. The first boundary element 260 is at the first threaded portion 188 the hub shaft 184 attached. This limits axial movement of the inner ring 254 ,

The hub shell 182 houses a connection unit 264 attached to the first bearing seat 244 is coupled to the outer ring 250 of the first camp 192 to hold, and a bearing retainer 266 attached to the hub shaft 184 is coupled and the inner ring 248 of the first camp 192 holds. The holder 204 that is the first side portion holds a terminal holding member 272 ,

As in 18 shown includes the terminal unit 264 Sections of the first wire 88 and the seventh wire 100 that the controller 44 and the control substrate 132 connect electrically.

As in 19 shown includes the first terminal unit 264 a first connection 268 , a second connection 270 and the cylindrical terminal holding member 272 that the first connection 268 and the second port 270 holds. As in 18 shown are the first connection 268 and the second connection 270 in the hub shell 182 arranged.

The connection holding element 272 is made of an electrically insulating resin material. The connection holding element 272 includes a cylindrical section 274 and a flange 276 coming from one axial end of the cylindrical section 274 runs towards the inner peripheral side. A first coupling slot 274A which is the first connection 268 is coupled in the inner peripheral surface of the cylindrical portion 274 formed, and a second coupling slot 274B that connects to the second port 270 is coupled in the outer peripheral surface of the cylindrical portion 274 educated. The first coupling slot 274A and the second coupling slot 274B are spaced from each other in the circumferential direction. The first coupling slot 274A is a groove in which the outer peripheral surface of the cylindrical portion 274 is excluded to the inside, and the second coupling slot 274B is a groove in which the inner peripheral surface of the cylindrical portion 274 is excluded to the outside. As in 18 is shown is the terminal holding member 272 serving as the insulating member, between the first bearing 192 and the second camp 194 arranged. The connection holding element 272 isolated the first camp 192 and the second camp 194 electric.

The first connection 268 is at the first coupling slot 274 fixed for example by welding or an adhesive. The second connection 270 is removable to the second coupling slot 274B coupled. In this way, the terminal holding member holds 272 the first connection 268 ,

As in 20 shown is the first connection 268 Bent in an L shape. An end of the first connection 268 includes a slightly curved contact portion 268A which is formed.

As in 21 shown is the second port 270 Bent in an L shape. The second connection 270 includes a first bent portion 270A , a second bent portion 270B and a third bent portion 270C , which are each bent at a generally right angle. One end of the second connection 270 includes a slightly curved contact portion 270D ,

The bearing holding element 266 and the first limiting mechanism 230 will now be detailed with reference to the 22 to 25 described.

As in 22 shown includes the first bearing support member 266 a first cylindrical portion 278 , a second cylindrical section 280 having a larger outer diameter than the first cylindrical portion 278 , and a flange 282 which is the first cylindrical section 278 and the second cylindrical portion 280 coupled in the radial direction. A connection 284 is to the bearing support member 266 coupled.

The first cylindrical section 278 includes a connection coupling slot 278A , which has a groove for coupling the connection 284 is. A recess 280A partially extends in the circumferential direction in the distal end of the second cylindrical portion 280 , The flange 282 includes four breakthroughs 282A passing through the flange 282 in the axial direction. The four breakthroughs 282A are formed at intervals of 90 °.

The first holding plate 234 the first limiting mechanism 230 includes a shaft insertion hole 234A through which the hub shaft 184 is plugged in, and an insertion hole 234B extending in the radial direction from a part of the shaft insertion hole 234A extends.

Four openings 234C and two mounting holes 234D extend through the first retaining plate 234 at circumferential intervals around the shaft insertion hole 234A , The four openings 234C are formed at intervals of 90 °, and the two mounting holes 234D are formed at intervals of 180 °. Every attachment hole 234D is between the openings 234C formed adjacent in the circumferential direction.

The first holding plate 234 includes three turnstile elements 234E in the outer peripheral portion, which are arranged at certain intervals in the circumferential direction. Each turnstile element 234E is a tab extending from the outer peripheral edge of the first retaining plate 234 is bent.

The second holding plate 236 is bent so that it is around a part of the hub shaft 184 runs in the circumferential direction. The second holding plate 236 comprises a plate main body 236A and a shaft insertion portion 236B passing through the panel main body 236A in the axial direction. The hub shaft 184 is through the shaft insertion section 236B plugged in. The second holding plate 236 includes two extensions 236C connected to the shaft insertion section 236B are continuous and away from the plate main body 236A so that they cover the hub shaft 184 surround.

The plate main body 236A includes two openings 236D extending in the radial direction and two attachment hooks 236E that extend in the axial direction around the shaft insertion portion 236B are arranged around. A turnstile element 236F that extends in the radial direction is at the inner radial edge of each opening 236D and the outer radial edge of each extension 236C educated. The two fastening hooks 236E are arranged at intervals of 180 °, and the four rotation stop elements 236F are arranged at intervals of 90 °.

The locking nut 238 includes a cylindrical section 238A that is at the hub shaft 184 is fixed, and a flange 238B that extends radially from an axial end of the cylindrical portion 238A runs. The flange 238B is hexagonal when viewed in the axial direction.

As in 23 shown is the first holding plate 234 at an axial end of the first jaw 226 assembled. In this state, each rotation stop element 234E between adjacent first claws 226 arranged in the circumferential direction. The rotation stop element 234E is the first claw 226 bent over and between the first claws adjacent to the circumference 226 fitted. This limits the rotation of the first holding plate 234 relative to the anchor 216 ,

The first holding plate 234 is arranged so that the insertion hole 234B with the wire receiving section 186 the hub shaft 184 aligned in the circumferential direction.

The second holding plate 236 is at the first holding plate 234 fixed by the fastening hooks 236E in the mounting holes 234D (please refer 22 ) of the first holding plate 234 are fitted. In this state, the rotation stop elements are aligned 236F the second holding plate 236 with the four openings 234C the first holding plate 234 ,

As in 24 shown, contacts the locking nut 238 attached to the hub shaft 184 is coupled, the second holding plate 236 , In this state, the four rotation stop elements 236F the second holding plate 236 to the locking nut 238 bent so that the four rotation stop elements 236F flat sections in the side surfaces of the flange 238B the locking nut 238 to contact. This limits the rotation of the locking nut 238 relative to the second holding plate 236 ,

A first supply wire 286 which serves as a conductive wire is at a starting end of the winding of the coil 224 (please refer 18 ) connected. A second supply wire 288 which serves as a conductive wire is connected to a terminal end of the winding of the coil 224 connected. The first supply wire 286 and the second lead wire 288 are in the wire receiving section 186 of the hub shaft 184 taken up and run through the Welleneinsteckabschnitt 236B the first holding plate 234 and the inside of the locking nut 238 , The first supply wire 286 and the second lead wire 288 are with a converter 82 (please refer 18 ) of the controller 44 connected. In this way, the power supply device comprises 170 (please refer 2 ) the first lead wire 286 serving as the first wire and the second lead wire 288 , which serves as the second wire to the power generator, which is the coil 224 includes, with the transducer 82 the controller 44 electrically connect.

As in 25 shown is the bearing support member 266 to the hub shaft 184 coupled to the locking nut 238 (please refer 24 ) Cover and the first holding plate 234 and the second holding plate 236 to contact. The second holding plate 236 is in the recess 280A of the bearing holding element 266 fitted. This limits the rotation of the bearing support member 266 relative to the second holding plate 236 ,

The structure of the first warehouse 192 and the second camp 194 will now be referring to 26 described.

The first camp seat 244 includes an annular groove 244B by removing a part of the first seat section 244A is formed in the axial direction. The flange 276 of the terminal holding member 272 the connection unit 264 is in the circular annular groove 244B accommodated.

The second seat section 246 includes a cylindrical section 290 extending in the axial direction and a flange 292 extending to the inner side in the radial direction from the end of the cylindrical portion 290 extends to the anchor 216 closer side. The cylindrical section 290 includes a groove 290A , The groove 290A extends in the axial direction on the side closer to the anchor 216 located. A breakthrough 292A passes through the flange 292 in the axial direction in communication with the groove 290A ,

The first connection 268 the connection unit 264 is with the connection holding element 272 coupled to the end of the cylindrical section 274 in the terminal holding member 272 on the side of the anchor 216 cover. As in 26 shown is the first connection 268 between the outer ring 250 of the first camp 192 and the cylindrical section 274 of the terminal holding member 272 held. The contact section 268A of the first connection 268 contacts the outer ring 250 of the first camp 192 ,

The second connection 270 the connection unit 264 is with the connection holding element 272 coupled to the end on the side of the first bearing 192 and the flange 276 in the cylindrical section 274 of the terminal holding member 272 cover. The second connection 270 is between the terminal holding member 272 and the holder 204 held. The second connection 270 is in the breakthrough 292A of the second bearing section 246 the holder 204 plugged in. The contact section 270D of the second connection 270 is in the groove 290A of the second seat section 246 added. As in 26 shown contacts the contact section 270D the outer ring 256 of the second camp 194 , As in 26 Further, the second port is shown 270 between the bracket 204 and the second camp 194 held.

The bearing holding element 266 holds the inner ring 248 of the first camp 192 with the flange 282 and the first cylindrical portion 278 , The connection 284 attached to the first cylindrical section 278 coupled, contacted the inner ring 248 ,

A conduction path of the first wire 88 and the seventh wire 100 will now be described.

The first wire 88 includes a first conductive wire 88A who with the controller 44 (please refer 18 ), and a second conductive wire 88B that with the control substrate 132 connected is. The first conductive wire 88A is with the converter 82 the controller 44 electrically connected. As in 26 shown is the first conductive wire 88A which is in the wire receiving section 186 the hub shaft 184 is included, with the connection 284 of the bearing holding element 266 connected. The second conductive wire 88B is with the first connection 268 connected, and is in a first insertion hole 294 the holder 204 plugged in. The second conductive wire 88B extends from the hub shell 182 from the first insertion hole 294 and is with the control substrate 132 at the back of the first wheel cover 116A (please refer 12 and 14 ) connected.

The rolling elements 252 each contact the inner ring 248 and the outer ring 250 , Thus, the first camp forms 192 the conduction path, which is the first conductive wire 88A and the second conductive wire 88B connects electrically. In other words, the first camp forms 192 a first power transmission unit located between the hub shell 182 and the hub shaft 184 is arranged. Accurate forms at the first camp 192 the outer ring 250 , which integrates with the hub shell 182 turns, a first electrical contact. The inner ring 248 that is at the hub shaft 184 through the bearing support member 266 is held and is carried so that a rotation relative to the hub shaft 184 is limited forms a second electrical contact. The first electrical contact and the second electrical contact are through the rolling elements 252 electrically connected. The first connection 268 contacts the outer ring 250 of the first camp 192 so the first connection 268 connected to the first electrical contact. In this way, the first wire 88 through the first conductive wire 88A , the connection 284 of the bearing holding element 266 , the first camp 192 , the first connection 268 and the second conductive wire 88B educated.

The seventh wire 100 includes a first conductive wire 100A who with the controller 44 is connected, and a second conductive wire 100B that with the control substrate 132 connected is. The first conductive wire 100A is with the converter 82 the controller 44 electrically connected. As in 26 shown is the first conductive wire 100A which is in the wire receiving section 186 the hub shaft 184 is included, with the inner ring 254 of the second camp 194 connected. The second conductive wire 100B that with the second connection 270 is connected, is in a second insertion hole 296 the holder 204 plugged in. The second conductive wire 100B extends from the hub shell 182 from the second insertion hole 296 and is with the control substrate 132 at the back of the first wheel cover 116A connected.

The rolling elements 258 each contact the inner ring 254 and the outer ring 256 , Thus, the second camp forms 194 the conduction path to the first conductive wire 100A and the second port 270 electrically connect. In other words, the second camp forms 194 a second power transmission unit located between the hub shell 182 and the hub shaft 184 is arranged. Accurate forms at the second camp 194 the outer ring 256 , which integrates with the hub shell 182 turns, a third electrical contact. The inner ring 254 that is at the hub shaft 184 is fixed, forms a fourth electrical contact. The second camp 194 electrically connects the third electrical contact and the fourth electrical contact with the rolling elements 258 , The second connection 270 contacts the outer ring 256 of the second camp 194 , Thus, the second port is 270 connected to the third electrical contact. In this way, the seventh wire 100 thus through the first conductive wire 100A , the second camp 194 , the second connection 270 and the second conductive wire 100B educated.

As in 27 shown are the first connection 268 and the second connection 270 spaced in the circumferential direction. The first insertion hole 294 and the second insertion hole 296 are spaced in the circumferential direction. The distance in the circumferential direction between the radially outer end of the first terminal 268 and the radially outer end of the second terminal 270 is larger than the distance in the circumferential direction between the first insertion hole 294 and the second insertion hole 296 ,

The operation of the present embodiment will now be described.

First, the operations that affect the hub dynamo 180 refer described.

The rotation of the front wheel 14 turns the permanent magnet 218 relative to the anchor 216 , As a result, an electromagnetic induction generates alternating current in the coil 224 of the anchor 216 , The first supply wire 286 and the second lead wire 288 deliver that through the coil 224 generated AC power to the controller 44 , In the control 44 becomes the alternating current of the coil 224 through the converter 82 converted into direct current and the first conductive wire 88A of the first wire 88 fed.

The first conductive wire 88A supplies the control circuit 56 that integrates with the front wheel 14 turns, over the first camp 192 and the second conductive wire 88B with the direct current. Then the control circuit emits 56 Light from each of the light source units 48 . 50 . 52 . 54 ,

At the first camp 192 connect the rolling elements 252 the inner ring 248 that is not integral with the front wheel 14 turns, and the outer ring 250 that integrates with the front wheel 14 turns, electrically. At the second camp 194 connect the rolling elements 258 the inner ring 254 that is not integral with the front wheel 14 turns, and the outer ring 256 that integrates with the front wheel 14 turns, electrically. Thus, DC is from the controller 44 that are not integral with the front wheel 14 turns, the control circuit 56 fed, which is integral with the front wheel 14 rotates.

The operation of the light emitting units 42A . 42B will now be described.

For example, if the control circuit 56 Light from the first light source 58 the first light source unit 48 emitted, the light enters the first light source 58 in the first incidence area 136A of the first light guide element 136 one. The light that is in the first incidence area 136A occurs, is the reflection pattern 136D reflected, that at the first reflection surface 136B is formed, and emerges from the side surface of the first wheel cover 116A through the first light emission surface 136C and the first translucent cover 152 out. Thus, the entire first light emitting surface emits 136C of the first light guide element 136 Light over the entire circumferential direction. The second light guide element 138 , the third optical fiber element 140 and the fourth optical fiber element 142 emit light in the same way. Light appears to be from a ring through the light guide elements 136 . 138 . 140 . 142 emitted when the first wheel cover 116A viewed from the side surface.

In particular, light is apparently emitted from a ring when the first wheel cover 116A and the second wheel cover 116B from the side during the rotation of the front wheel 14 to be viewed as. If the front wheel 14 stops rotating, emit the first light source unit 48 and the second light source unit 50 for a certain period of time light due to the capacitor 84 the controller 44 which is charged when the front wheel 14 rotates. Even if the wheel 14 thus, light stops appearing to be emitted from a ring for a certain period of time when the first wheel cover stops 116A and the second wheel cover 116B be viewed from the side surface. The same operation is at the rear wheel 16 carried out.

• (1) Die Lichtemittiereinheit 42A umfasst die erste Lichtquelle 58, die sich integral mit dem Vorderrad 14 dreht, und das erste Lichtleiterelement 136, das sich integral mit dem Vorderrad 14 dreht. Solange die erste Lichtquelle 58 Licht emittiert, emittiert somit das erste Lichtleiterelement 136 in seiner Gesamtheit Licht. Somit hängt die visuelle Wirkung der Lichtemittiereinheit 42A nicht stark von der Drehgeschwindigkeit des Vorderrades 14 ab.
• (2) Die erste Lichtquelle 58 ist im Wesentlichen parallel zu einer Richtung, die zu der Drehachse des Vorderrades 14 orthogonal ist. Verglichen dazu, dass die erste Lichtquelle 58 das erste Lichtleiterelement 136 in einer Richtung parallel zur Drehachse des Vorderrades 14 bestrahlt, wird somit Licht von einem breiteren Bereich des ersten Lichtleiterelements 136 emittiert. Derselbe Vorteil wird durch die zweite Lichtquelle 60 und das zweite Lichtleiterelement 138, die dritte Lichtquelle 64 und das dritte Lichtleiterelement 140 und die vierte Lichtquelle 66 und das vierte Lichtleiterelement 142 erreicht.
• (3) Das erste Lichtleiterelement 136 verläuft entlang der Seitenfläche der ersten Radabdeckung 116A. Verglichen beispielsweise mit einer Ausbildung, in der das erste Lichtleiterelement 136 in einer Richtung parallel zur Drehachse des Vorderrades 14 verläuft, wird somit Licht von einem breiteren Bereich emittiert, wenn die erste Radabdeckung 116A von der Seite betrachtet wird. Derselbe Vorteil wird durch das zweite Lichtleiterelement 138, das dritte Lichtleiterelement 140 und das vierte Lichtleiterelement 142 erreicht.
• (4) Die Lichtemittiereinheit 42A umfasst des Weiteren die zweite Lichtquelle 60, die sich integral mit dem Vorderrad 14 dreht, und das zweite Lichtleiterelement 138, das sich integral mit dem Vorderrad 14 dreht. Somit kann ein breiterer Bereich Licht emittieren, wenn die erste Radabdeckung 116A von der Seitenfläche aus betrachtet wird. Die Lichtemittiereinheit 42A umfasst des Weiteren die dritte Lichtquelle 64 und die vierte Lichtquelle 66 und das dritte Lichtleiterelement 140 und das vierte Lichtleiterelement 142, so dass ein breiterer Bereich in der ersten Radabdeckung 116A Licht emittiert.
• (5) Das erste Lichtleiterelement 136 und das zweite Lichtleiterelement 138 sind in der Umfangsrichtung angeordnet. Dies verbreitert den Bereich, der Licht in der Umfangsrichtung emittiert, wenn die erste Radabdeckung 116A von der Seitenfläche aus betrachtet wird. Auch wenn das Vorderrad 14 mit einer geringeren Geschwindigkeit gedreht wird, erscheint somit der Bereich, der Licht emittiert, ohne weiteres als ein Ring.
• (6) Die erste Lichtquelle 58 und die zweite Lichtquelle 60 sind an dem ersten Montagesubstrat 62 montiert. Verglichen mit einem Aufbau, der Montagesubstrate umfasst, auf denen die erste Lichtquelle 58 und die zweite Lichtquelle 60 montiert sind, ist somit die Anzahl an Komponenten der Lichtemittiereinheit 42A reduziert. Ferner ist der Abstand in der Umfangsrichtung zwischen der ersten Einfallfläche 136A des ersten Lichtleiterelements 136 und der zweiten Einfallfläche 138A des zweiten Lichtleiterelements 138 verringert. Derselbe Vorteil wird auch durch die dritte Lichtquelle 64, die vierte Lichtquelle 66 und das zweite Montagesubstrat 68 erreicht.
• (7) Die Dicke des ersten Lichtleiterelements 136 ist von einem Ende, wo die erste Einfallfläche 136A ausgebildet ist, zum anderen Ende in der Umfangsrichtung verringert. Genauer ist die erste Reflektionsfläche 136B geneigt, um sich der optischen Achse der ersten Lichtquelle 58 von einem Ende zum anderen Ende hin anzunähern. Dies bestrahlt ohne weiteres das Reflektionsmuster 136D mit dem Licht von der ersten Lichtquelle 58. Somit tritt das Licht der ersten Lichtquelle 58 effizient aus der ersten Lichtemissionsfläche 136C aus. Derselbe Vorteil wird durch das zweite Lichtleiterelement 138, das dritte Lichtleiterelement 140 und das vierte Lichtleiterelement 142 erreicht.
• (8) Das Reflektionsmuster 136D an der ersten Reflektionsfläche 136B des ersten Lichtleiterelements 136 weist eine Dichteverteilung auf, die in der Umfangsrichtung variiert. Dies variiert den Grad des Lichts von der ersten Lichtquelle 58, das aus der ersten Lichtemissionsfläche 136C austritt. Derselbe Vorteil wird durch das zweite Lichtleiterelement 138, das dritte Lichtleiterelement 140 und das vierte Lichtleiterelement 142 erreicht.
• (9) Die Dichte des Reflektionsmusters 136D im dritten Bereich R3 der ersten Reflektionsfläche 136B ist kleiner als die Dichte des Reflektionsmusters 136D im ersten Bereich R1 der ersten Reflektionsfläche 136B und die Dichte des Reflektionsmusters 136D im zweiten Bereich R2. Dies verringert die Unterschiede beim Licht des ersten Bereichs R1 bis zum dritten Bereich R3, wenn das Licht der ersten Lichtquelle 58 aus der ersten Lichtemissionsfläche 136C austritt.
• (10) Das Steuersubstrat 132 wird durch die erste Radabdeckung 116A und die zweite Radabdeckung 116B gehalten. Somit kann der Steuerung 44 im Vergleich dazu miniaturisiert werden, wenn die Steuerung 44 das Steuersubstrat 132 umfasst.
• (11) Das Steuersubstrat 132 wird zwischen dem Abdeckungskörper 122 der ersten Radabdeckung 116A und dem Abdeckungskörper 122 der zweiten Radabdeckung 116B gehalten. Somit kann jede der Hauptflächen 132A, 132B des Steuersubstrats 132 entlang der axialen Richtung angeordnet werden. Dies ermöglicht es dem Steuersubstrat 132, den Speichern 28 des Vorderrads 14 aus dem Weg zu gehen.
• (12) Jeder der durchscheinenden Abdeckungen 152, 154, 156, 158 ist an die erste Radabdeckung 116A gekoppelt, um die erste Lichtquelleneinheit 48 und die zweite Lichtquelleneinheit 50 abzudecken. Dies begrenzt das Eindringen von Fremdkörpern, wie etwa Wasser und Staub, in die erste Lichtquelleneinheit 48 und die zweite Lichtquelleneinheit 50.
• (13) Das erste Befestigungselement 160 und das zweite Befestigungselement 162, die Licht abschirmende Eigenschaften aufweisen, sind an den Felgenkopplungsabschnitt 126 gekoppelt, um die erste Lichtquelleneinheit 48 bzw. die zweite Lichtquelleneinheit 50 abzudecken. Somit bleibt das Licht des ersten Lichtleiterelements 136 und des zweiten Lichtleiterelement 138 weiter außenstehend.
• (14) Jedes der Befestigungselemente 160, 162, 164, 166 ist mit dem Felgenkopplungsabschnitt 126 dadurch gekoppelt, dass die Haken 160A, 162A, 164A, 166A in die entsprechenden Kopplungslöcher 126A eingepasst sind. Dies erleichtert das Koppeln der Befestigungselemente 160, 162, 164, 166 an den Felgenkopplungsabschnitt 126, und ermöglicht es, dass die durchscheinenden Abdeckungen 152, 154, 156, 158 durch den Halteabschnitt 128 gehalten werden.
• (15) Die Lichtleiterelemente 136, 138, 140, 142, die bogenförmig sind, sind in der Umfangsrichtung angeordnet, um einen Ring zu bilden. Auch wenn die Drehgeschwindigkeit des Vorderrads 14 niedrig ist, emittieren somit die erste Radabdeckung 116A und die zweite Radabdeckung 116B jeweils Licht in der Form eines Rings.
• (16) Der Halteabschnitt 128 ist so ausgebildet, dass der erste Halteabschnitt 128A, der zweite Halteabschnitt 128B und der dritte Halteabschnitt 128C in dieser Reihenfolge in der Breite verkleinert sind. Somit ist jedes der Trageelemente 148, 150 und jedes der Lichtleiterelemente 136, 138, 140, 142 nicht an den dritten Halteabschnitt 128C gekoppelt. Ferner ist jeder der durchscheinenden Abdeckungen 152, 154, 156, 158 nicht an den zweiten Halteabschnitt 128B gekoppelt.
• (17) Der erste Halteabschnitt 128A, der zweite Halteabschnitt 128B und der dritte Halteabschnitt 128C sind in der axialen Richtung gesehen an überlappenden Positionen ausgebildet und weisen die Form von Nuten auf, die miteinander in Kommunikation sind. Dies vereinfacht die Form der ersten Radabdeckung 116A verglichen mit dem Fall, in dem der dritte Halteabschnitt 128C an der radial inneren Seite oder äußeren Seite des ersten Halteabschnitts 128A und des zweiten Halteabschnitts 128B ausgebildet ist. Der zweite Draht 90, der dritte Draht 92, der vierte Draht 94, der fünfte Draht 96 und der sechste Draht 98 sind zwischen dem dritten Halteabschnitt 128C einer der Radabdeckungen 116A, 116B und jedem der Trageelemente 148, 150 gehalten. Dies hält die Drahtgruppe 46A im dritten Halteabschnitt 128C. Dies beseitigt die Notwendigkeit für ein Element, das dazu bestimmt ist, die Drahtgruppe 46A in dem dritten Halteabschnitt 128C zu halten, und vereinfacht die Struktur der Lichtemittiereinheit 42A.
• (18) Jedes Einsteckloch 126D, 126E, 126F, 126G ist in dem Felgenkopplungsabschnitt 126 ausgebildet. Somit ist die Drahtgruppe 46A in derselben Weise verlegt, unabhängig davon, welche der Radabdeckungen der ersten Radabdeckung 116A und der zweiten Radabdeckung 116B verwendet wird.
• (19) Jede der Hauptflächen 62A, 62B des ersten Montagesubstrats 62 und jede der Hauptflächen 68A, 68B des zweiten Montagesubstrats 68 sind parallel zur Axialrichtung angeordnet. Die verringert den Abstand in der Umfangsrichtung zwischen dem ersten Lichtleiterelement 136 und dem zweiten Lichtleiterelement 138 und den Abstand zwischen dem dritten Lichtleiterelement 140 und dem vierten Lichtleiterelement 142. Daher wird die Umfangslänge jedes der Lichtleiterelemente 136, 138, 140, 142 erhöht.
• (20) Das Steuersubstrat 132 ist an einer Position benachbart zum ersten Montagesubstrat 62 angeordnet. Dies verkürzt den zweiten Draht 90, der das Steuersubstrat 132 und das erste Montagesubstrat 62 verbindet.
• (21) Die Drahtgruppe 46A ist mit den Hauptflächen 132A, 132B des Steuersubstrats 132 verbunden. Somit ist die Größe des Steuersubstrats 132 im Vergleich damit verringert, wenn die Drahtgruppe 46A mit nur einer Fläche des Steuersubstrats 132 verbunden ist.
• (22) Das erste Lager 192 umfasst den äußeren Ring 250, der sich integral mit dem Nabengehäuse 182 dreht, den inneren Ring 248, der an der Nabenwelle 184 durch das Lagerhalteelement 266 gehalten wird, und die Rollelemente 252, die eine elektrische Verbindung des äußeren Rings 250 und des inneren Rings 248 ermöglichen. Somit sind das Nabengehäuse 182 und die Nabenwelle 184 durch das erste Lager 192 elektrisch verbunden. Ferner ist der Drehwiderstand des Nabengehäuses 182 im Vergleich dazu verringert, dass das Nabengehäuse 182 und die Nabenwelle 184 mit einem Metallkontakt elektrisch verbunden werden, der wie ein Gleitring gleitet.
• (23) Das zweite Lager 194 umfasst den äußeren Ring 256, der sich integral mit dem Nabengehäuse 182 dreht, den inneren Ring 254, der an der Nabenwelle 184 fixiert ist, und die Rollelemente 258, was eine elektrische Verbindung des äußeren Rings 256 und des inneren Rings 254 ermöglicht. Dies stellt eine elektrische Verbindung zwischen dem Nabengehäuse 182 und der Nabenwelle 184 mit dem zweiten Lager 194 sicher. Ferner ist der Drehwiderstand des Nabengehäuses 182 im Vergleich dazu verringert, dass das Nabengehäuse 182 und die Nabenwelle 184 mit einem Metallkontakt elektrisch verbunden werden, der wie ein Gleitring gleitet.
• (24) Der erste Anschluss 268 und der zweite Anschluss 270 sind in dem Nabengehäuse 182 angeordnet. Somit ist es weniger wahrscheinlich, dass sich Wasser an dem ersten Anschluss 268 und dem zweiten Anschluss 270 ansammelt, verglichen damit, dass der erste Anschluss 268 und der zweite Anschluss 270 außerhalb des Nabengehäuses 182 angeordnet sind. Dies begrenzt die Korrosion des ersten Anschlusses 268 und des zweiten Anschlusses 270.
• (25) Die Anschlusseinheit 264 umfasst das Anschlusshalteelement 272, das elektrisch isolierende Eigenschaften aufweist und den ersten Anschluss 268 und den zweiten Anschluss 270 hält. Dies löst die Verbindung des ersten Anschlusses 268 und des zweiten Anschlusses 270.
• (26) Der zweite Anschluss 270 ist zwischen dem Anschlusshalteelement 272 und dem ersten Lagersitz 244 der Halterung 204 gehalten. Somit sind der zweite Anschluss 270 und das Anschlusshalteelement 272 fixiert, ohne die Notwendigkeit einer Form oder eines Verfahrens, die dazu bestimmt sind, den zweiten Anschluss 270 und das Anschlusshalteelement 272 zu fixieren. Dies vereinfacht die Formen des zweiten Anschlusses 270 und des Anschlusshalteelements 272.
• (27) Der erste Zuleitungsdraht 286 und der zweite Zuleitungsdraht 288 sind in dem Drahtaufnahmeabschnitt 186 der Nabenwelle 184 aufgenommen. Somit können der erste Zuleitungsdraht 286 und der zweiten Zuleitungsdraht 288 ohne weiteres sich aus dem Nabengehäuse 182 erstrecken.
• (28) Der erste leitfähige Draht 88A des ersten Drahts 88 und der erste leitfähige Draht 100A des siebten Drahts 100, die mit der Steuerung 44 verbunden sind, sind auch in dem Drahtaufnahmeabschnitt 186 der Nabenwelle 184 aufgebracht. Somit sind vier Drähte, der erste Zuleitungsdraht 286, der zweite Zuleitungsdraht 288, der erste leitfähige Draht 88A und der erste leitfähige Draht 100A in dem Drahtaufnahmeabschnitt 186 aufgenommen, der die Form einer Nut aufweist. Dies vereinfacht die Form der Nabenwelle 184 verglichen beispielsweise damit, dass ein Drahtaufnahmeabschnitt für jeden leitfähigen Draht gebildet wird.
• (29) Der erste Sitzabschnitt 244A, an den das erste Lager 192 gekoppelt ist, und der zweite Sitzabschnitt 246, an den das zweite Lager 194 gekoppelt ist, sind im ersten Lagersitz 244 der Halterung 204 ausgebildet. Dies verringert die Anzahl an Komponenten des Nabendynamos 180 verglichen damit, dass einer von dem ersten Sitzabschnitt 244A und dem zweiten Sitzabschnitt 246 mit einem von der Halterung 204 getrennt ausgebildeten Element versehen wird.
• (30) Bei dem ersten Begrenzungsmechanismus 230 ist jeder der drei Drehstoppelemente 234E der ersten Halteplatte 234 zwischen benachbarten ersten Klauen 226 in der Umfangsrichtung eingepasst. Dies begrenzt eine Bewegung in der Umfangsrichtung der ersten Halteplatte 234 relativ zu den ersten Klauen 226. Daher wird an dem ersten Zuleitungsdraht 286 und dem zweiten Zuleitungsdraht 288, die in das Einsteckloch 234B der ersten Halteplatte 234 eingesteckt sind, nicht durch die Umfangsbewegung der ersten Halteplatte 234 gezogen.
• (31) Bei dem ersten Begrenzungsmechanismus 230 werden die erste Halteplatte 234 und die zweite Halteplatte 236 zwischen der Feststellmutter 238 und den ersten Klauen 226 gehalten. Die vier Drehstoppelemente 236F der zweiten Halteplatte 236, die an der ersten Halteplatte 234 fixiert sind, kontaktieren die Seitenflächen des Flanschs 238B der Feststellmutter 238. Dies begrenzt die Drehung der Feststellmutter 238. Wenn eine Drehung der Feststellmutter 238 die Feststellmutter 238 von der zweiten Halteplatte 236 weg in der axialen Richtung bewegt, wird die Bewegung der ersten Halteplatte 234 und der zweiten Halteplatte 236 in der axialen Richtung begrenzt. Dies begrenzt die Abtrennung des Drehstoppelements 234E der ersten Halteplatte 234 von den ersten Klauen 226, die bewirkt würde, wenn die erste Halteplatte 234 sich von den ersten Klauen 226 in der axialen Richtung wegbewegt.
• (32) Die Aussparung 280A des Lagerhalteelements 266 ist an die zweite Halteplatte 236 gepasst. Die zweite Halteplatte 236 ist an der ersten Halteplatte 234 fixiert, und die Drehung der zweiten Halteplatte 236 wird durch das Drehstoppelement 234E der ersten Halteplatte 234 begrenzt. Dies begrenzt die Drehung des Lagerhalteelements 266, das an die zweite Halteplatte 236 gepasst ist. Daher wird nicht an dem ersten leitfähigen Draht 88A des ersten Drahts 88 gezogen, der mit dem Anschluss 284 des Lagerhalteelements 266 verbunden ist, wenn das Lager des Lagerhalteelements 266 sich dreht.
• (33) Das Lagerhalteelement 266 nimmt die Feststellmutter 238 auf. Somit ist der Nabendynamo 180 in seiner Größe in der axialen Richtung verringert, verglichen damit, dass das Lagerhalteelement 266 und die Feststellmutter 238 in der axialen Richtung beabstandet sind.
• (34) Das Lagerhalteelement 266, das elektrische Isoliereigenschaften aufweist, hält das zweite Lager 194. Dies isoliert die Nabenwelle 184 und die ersten Klauen 226 elektrisch von dem zweiten Lager 194.
• (35) Bei dem ersten Anschluss 268 ist der Kontaktabschnitt 268A, der den äußeren Ring 250 des ersten Lagers 192 kontaktiert, gebogen. Somit drückt der Kontaktabschnitt 268A konstant gegen den äußeren Ring 250. Dies hält den ersten Anschluss 268 und das zweite Lager 192 stabil in Kontakt miteinander.
• (36) Bei dem zweiten Anschluss 270 ist der Kontaktabschnitt 270D, der den äußeren Ring 256 des zweiten Lagers 194 kontaktiert, gebogen. Somit drückt der Kontaktabschnitt 270D konstant gegen den äußeren Ring 256. Dies hält den zweiten Anschluss 270 und das zweite Lager 194 stabil in Kontakt miteinander.
• (37) Die Stromversorgungsvorrichtung 170 umfasst den Kondensator 84. Somit versorgt der Kondensator 84 jede der Lichtquelleneinheiten 48, 50, 52, 54 mit Gleichstrom, auch wenn das Vorderrad 14 aufhört, sich zu drehen und der Nabendynamo 180 keinen Wechselstrom erzeugt. Somit emittiert jede der Lichtquelleneinheiten 48, 50, 52, 54 für eine bestimmte Zeitdauer Licht, auch nachdem das Vorderrad 14 aufhört sich zu drehen.

The present embodiment has the following advantages. The second wheel cover 116B and the light emitting unit 42B also have the same advantages.

• (1) The light emitting unit 42A includes the first light source 58 that integrates with the front wheel 14 rotates, and the first light guide element 136 that integrates with the front wheel 14 rotates. As long as the first light source 58 Emits light, thus emits the first light guide element 136 in its entirety light. Thus, the visual effect of the light emitting unit depends 42A not strong on the rotational speed of the front wheel 14 from.
• (2) The first light source 58 is substantially parallel to a direction parallel to the axis of rotation of the front wheel 14 is orthogonal. Compared to that the first light source 58 the first light guide element 136 in a direction parallel to the axis of rotation of the front wheel 14 Thus, light is irradiated from a wider area of the first light guide element 136 emitted. The same advantage is provided by the second light source 60 and the second optical fiber element 138 , the third light source 64 and the third optical fiber element 140 and the fourth light source 66 and the fourth optical fiber element 142 reached.
• (3) The first light guide element 136 runs along the side surface of the first wheel cover 116A , For example, compared with an embodiment in which the first optical fiber element 136 in a direction parallel to the axis of rotation of the front wheel 14 Thus, light is emitted from a wider area when the first wheel cover 116A viewed from the side. The same advantage is achieved by the second optical fiber element 138 , the third optical fiber element 140 and the fourth optical fiber element 142 reached.
• (4) The light emitting unit 42A further comprises the second light source 60 that integrates with the front wheel 14 rotates, and the second light guide element 138 that integrates with the front wheel 14 rotates. Thus, a wider area may emit light when the first wheel cover 116A viewed from the side surface. The light emitting unit 42A further includes the third light source 64 and the fourth light source 66 and the third optical fiber element 140 and the fourth optical fiber element 142 so that a wider area in the first wheel cover 116A Emitted light.
• (5) The first light guide element 136 and the second optical fiber element 138 are arranged in the circumferential direction. This widens the area that emits light in the circumferential direction when the first wheel cover 116A viewed from the side surface. Even if the front wheel 14 is rotated at a lower speed, thus, the area that emits light readily appears as a ring.
• (6) The first light source 58 and the second light source 60 are on the first mounting substrate 62 assembled. Compared with a structure comprising mounting substrates on which the first light source 58 and the second light source 60 are mounted, thus the number of components of the light emitting unit 42A reduced. Further, the distance in the circumferential direction is between the first incident surface 136A of the first light guide element 136 and the second incident surface 138A the second light guide element 138 reduced. The same advantage is also due to the third light source 64 , the fourth light source 66 and the second mounting substrate 68 reached.
• (7) The thickness of the first optical fiber element 136 is from an end where the first incidence area 136A is formed, reduced to the other end in the circumferential direction. More precisely, the first reflection surface 136B inclined to the optical axis of the first light source 58 approach from one end to the other. This readily irradiates the reflection pattern 136D with the light from the first light source 58 , Thus, the light of the first light source occurs 58 efficient from the first light emission surface 136C out. The same advantage is achieved by the second optical fiber element 138 , the third optical fiber element 140 and the fourth optical fiber element 142 reached.
• (8) The reflection pattern 136D at the first reflection surface 136B of the first light guide element 136 has a density distribution that varies in the circumferential direction. This varies Degree of light from the first light source 58 that is from the first light emission surface 136C exit. The same advantage is achieved by the second optical fiber element 138 , the third optical fiber element 140 and the fourth optical fiber element 142 reached.
• (9) The density of the reflection pattern 136D in the third region R3 of the first reflection surface 136B is smaller than the density of the reflection pattern 136D in the first region R1 of the first reflection surface 136B and the density of the reflection pattern 136D in the second area R2. This reduces the differences in the light of the first region R1 to the third region R3 when the light of the first light source 58 from the first light emission surface 136C exit.
• (10) The control substrate 132 gets through the first wheel cover 116A and the second wheel cover 116B held. Thus, the controller 44 In comparison, miniaturized when the controller 44 the control substrate 132 includes.
• (11) The control substrate 132 is between the cover body 122 the first wheel cover 116A and the cover body 122 the second wheel cover 116B held. Thus, each of the main surfaces 132A . 132B of the control substrate 132 be arranged along the axial direction. This allows the control substrate 132 , the save 28 of the front wheel 14 to get out of the way.
• (12) Each of the translucent covers 152 . 154 . 156 . 158 is at the first wheel cover 116A coupled to the first light source unit 48 and the second light source unit 50 cover. This limits the penetration of foreign matter such as water and dust into the first light source unit 48 and the second light source unit 50 ,
• (13) The first fastener 160 and the second fastening element 162 that have light-shielding properties are at the rim coupling portion 126 coupled to the first light source unit 48 or the second light source unit 50 cover. Thus, the light of the first light guide element remains 136 and the second optical fiber element 138 further outward.
• (14) Each of the fasteners 160 . 162 . 164 . 166 is with the rim coupling section 126 coupled by that the hook 160A . 162A . 164A . 166A into the corresponding coupling holes 126A are fitted. This facilitates the coupling of the fasteners 160 . 162 . 164 . 166 to the rim coupling section 126 , and allows the translucent covers 152 . 154 . 156 . 158 through the holding section 128 being held.
• (15) The light guide elements 136 . 138 . 140 . 142 which are arcuate are arranged in the circumferential direction to form a ring. Even if the rotational speed of the front wheel 14 is low, thus emit the first wheel cover 116A and the second wheel cover 116B each light in the form of a ring.
• (16) The holding section 128 is formed so that the first holding portion 128A , the second holding section 128B and the third holding section 128C are reduced in width in this order. Thus, each of the support elements 148 . 150 and each of the light guide elements 136 . 138 . 140 . 142 not on the third holding section 128C coupled. Further, each of the translucent covers 152 . 154 . 156 . 158 not on the second holding section 128B coupled.
• (17) The first holding section 128A , the second holding section 128B and the third holding section 128C are formed at overlapping positions when viewed in the axial direction and have the shape of grooves communicating with each other. This simplifies the shape of the first wheel cover 116A compared with the case where the third holding portion 128C on the radially inner side or outer side of the first holding portion 128A and the second holding portion 128B is trained. The second wire 90 , the third wire 92 , the fourth wire 94 , the fifth wire 96 and the sixth wire 98 are between the third holding section 128C one of the wheel covers 116A . 116B and each of the carrying elements 148 . 150 held. This holds the wire group 46A in the third holding section 128C , This eliminates the need for an element that is destined to the wire group 46A in the third holding section 128C and simplifies the structure of the light emitting unit 42A ,
• (18) Each insertion hole 126D . 126E . 126F . 126G is in the rim coupling section 126 educated. Thus, the wire group 46A laid in the same way, regardless of which of the wheel covers the first wheel cover 116A and the second wheel cover 116B is used.
• (19) Each of the main surfaces 62A . 62B of the first mounting substrate 62 and each of the main surfaces 68A . 68B of the second mounting substrate 68 are arranged parallel to the axial direction. This reduces the distance in the circumferential direction between the first optical fiber element 136 and the second optical fiber element 138 and the distance between the third optical fiber element 140 and the fourth optical fiber element 142 , Therefore, the circumferential length of each of the light guide elements becomes 136 . 138 . 140 . 142 elevated.
• (20) The control substrate 132 is at a position adjacent to the first mounting substrate 62 arranged. This shortens the second wire 90 that the tax substrate 132 and the first mounting substrate 62 combines.
• (21) The wire group 46A is with the main surfaces 132A . 132B of the control substrate 132 connected. Thus, the size of the control substrate 132 Compared with that, when the wire group decreases 46A with only one surface of the control substrate 132 connected is.
• (22) The first camp 192 includes the outer ring 250 , which integrates with the hub shell 182 turns, the inner ring 248 that is at the hub shaft 184 through the bearing support member 266 is held, and the rolling elements 252 which is an electrical connection of the outer ring 250 and the inner ring 248 enable. Thus, the hub shell 182 and the hub shaft 184 through the first camp 192 electrically connected. Furthermore, the rotational resistance of the hub shell 182 In comparison, this reduces the hub shell 182 and the hub shaft 184 be electrically connected to a metal contact, which slides like a sliding ring.
• (23) The second camp 194 includes the outer ring 256 , which integrates with the hub shell 182 turns, the inner ring 254 that is at the hub shaft 184 is fixed, and the rolling elements 258 What an electrical connection of the outer ring 256 and the inner ring 254 allows. This provides an electrical connection between the hub shell 182 and the hub shaft 184 with the second camp 194 for sure. Furthermore, the rotational resistance of the hub shell 182 In comparison, this reduces the hub shell 182 and the hub shaft 184 be electrically connected to a metal contact, which slides like a sliding ring.
• (24) The first connection 268 and the second connection 270 are in the hub shell 182 arranged. Thus, it is less likely that water will be on the first port 268 and the second port 270 accumulates, compared with that the first connection 268 and the second connection 270 outside the hub shell 182 are arranged. This limits the corrosion of the first port 268 and the second port 270 ,
• (25) The connection unit 264 includes the terminal holding member 272 which has electrically insulating properties and the first terminal 268 and the second port 270 holds. This triggers the connection of the first port 268 and the second port 270 ,
• (26) The second connection 270 is between the terminal holding member 272 and the first bearing seat 244 the holder 204 held. Thus, the second connection 270 and the terminal holding member 272 fixed, without the need for a mold or a method intended to make the second connection 270 and the terminal holding member 272 to fix. This simplifies the shapes of the second port 270 and the terminal holding member 272 ,
• (27) The first lead wire 286 and the second lead wire 288 are in the wire receiving section 186 the hub shaft 184 added. Thus, the first lead wire can 286 and the second lead wire 288 easily from the hub shell 182 extend.
• (28) The first conductive wire 88A of the first wire 88 and the first conductive wire 100A of the seventh wire 100 that with the controller 44 are also in the wire receiving section 186 the hub shaft 184 applied. Thus, four wires are the first lead wire 286 , the second lead wire 288 , the first conductive wire 88A and the first conductive wire 100A in the wire receiving section 186 received, which has the shape of a groove. This simplifies the shape of the hub shaft 184 compared, for example, that a wire-receiving portion for each conductive wire is formed.
• (29) The first seat section 244A to which the first camp 192 coupled, and the second seat portion 246 to which the second camp 194 is coupled in the first bearing seat 244 the holder 204 educated. This reduces the number of components of the hub dynamo 180 compared to that of the first seat section 244A and the second seat portion 246 with one of the bracket 204 is provided separately formed element.
• (30) In the first limiting mechanism 230 is each of the three turnstile elements 234E the first holding plate 234 between adjacent first claws 226 fitted in the circumferential direction. This limits movement in the circumferential direction of the first holding plate 234 relative to the first claws 226 , Therefore, on the first lead wire 286 and the second lead wire 288 in the insertion hole 234B the first holding plate 234 are plugged, not by the circumferential movement of the first holding plate 234 drawn.
• (31) In the first limiting mechanism 230 be the first holding plate 234 and the second holding plate 236 between the locking nut 238 and the first claws 226 held. The four turnstile elements 236F the second holding plate 236 attached to the first retaining plate 234 are fixed, contact the side surfaces of the flange 238B the locking nut 238 , This limits the rotation of the locking nut 238 , When a rotation of the locking nut 238 the locking nut 238 from the second holding plate 236 Moving away in the axial direction, the movement of the first holding plate 234 and the second holding plate 236 limited in the axial direction. This limits the separation of the rotary stop element 234E the first holding plate 234 from the first claws 226 that would be causing the first retaining plate 234 from the first claws 226 moved away in the axial direction.
• (32) The recess 280A of the bearing holding element 266 is to the second holding plate 236 fit. The second holding plate 236 is at the first holding plate 234 fixed, and the rotation of the second holding plate 236 is through the rotation stop element 234E the first holding plate 234 limited. This limits the rotation of the bearing support member 266 attached to the second retaining plate 236 is fit. Therefore, not on the first conductive wire 88A of the first wire 88 pulled that with the connection 284 of the bearing holding element 266 is connected when the bearing of the bearing support member 266 turns.
• (33) The bearing holding member 266 takes the locking nut 238 on. Thus, the hub dynamo 180 reduced in size in the axial direction, compared with that of the bearing support member 266 and the locking nut 238 are spaced in the axial direction.
• (34) The bearing holding member 266 having electrical insulating properties holds the second bearing 194 , This isolates the hub shaft 184 and the first claws 226 electrically from the second camp 194 ,
• (35) At the first connection 268 is the contact section 268A who is the outer ring 250 of the first camp 192 contacted, bent. Thus, the contact section presses 268A constant against the outer ring 250 , This keeps the first connection 268 and the second camp 192 stable in contact with each other.
• (36) At the second port 270 is the contact section 270D who is the outer ring 256 of the second camp 194 contacted, bent. Thus, the contact section presses 270D constant against the outer ring 256 , This holds the second port 270 and the second camp 194 stable in contact with each other.
• (37) The power supply device 170 includes the capacitor 84 , Thus, the capacitor supplies 84 each of the light source units 48 . 50 . 52 . 54 with DC, even if the front wheel 14 stops turning and the hub dynamo 180 does not generate an alternating current. Thus, each of the light source units emits 48 . 50 . 52 . 54 light for a certain period of time, even after the front wheel 14 stops turning.

It should be apparent to those skilled in the art that the subject matter of the present disclosure may be embodied in many other specific forms without departing from the scope of the invention. In particular, it should be understood that the subject matter of the present disclosure may be embodied in the following forms.

In the embodiment described above, any number of optical fiber elements can be specified.

In the embodiment described above, the light guide element may have any shape. For example, the light guide element may be annular.

In the embodiment described above, any number of light sources can be specified.

In the embodiment described above, the bicycle light emitting system may be a battery 298 include, which is integral with the front wheel 14 (please refer 3 ) and each of the light source units 48 . 50 through the control substrate 132 instead of the hub dynamo 180 supplied with direct current, as in 28 shown. Preferably, the battery is located 298 between the first wheel cover 116A and the second wheel cover 116B in the axial direction (see 12 ). The light emitting unit 42B may include a battery in the same way. The battery 298 can with the main frame 20 be coupled (see 1 ).

In the embodiment described above, it may be determined that the optical fiber element extends in each direction. For example, each of the first optical fiber element 300 , the second optical fiber element 302 and the third optical fiber element 304 be rectangular and oblong in the radial direction, as in 29 shown. The first light guide element 300 , the second optical fiber element 302 and the third optical fiber element 304 are arranged at intervals of 120 ° in the circumferential direction. The first light source 306 , which radially the inner end face of the first light guide element 300 irradiated, and the first mounting substrate 308 on which the first light source 306 are mounted on the inner radial end of the first optical fiber element 300 arranged. The second light source 310 that radially the inner end face of the second optical fiber element 302 irradiated, and the second mounting substrate 312 on which the second light source 310 are mounted on the radial inner end of the second optical fiber element 302 arranged. The third light source 314 that radially the inner end face of the third optical fiber element 304 irradiated, and the third mounting substrate 316 on which the third light source 314 are mounted on the inner end side in the radial direction of the third optical fiber element 304 arranged.

In the above-described embodiment, the first light source and the second light source need not be arranged between the first light guide member and the second light guide member in the circumferential direction. As in 29 are shown, for example, the first light source 306 , the second light source 310 and the third light source 314 not in the circumferential direction between the first optical fiber element 300 , the second optical fiber element 302 and the third optical fiber element 304 arranged adjacent to each other in the circumferential direction.

In the embodiment described above, the first optical fiber element 318 , the second optical fiber element 320 , the third optical fiber element 322 and the fourth optical fiber element 324 which serve as four rectangular optical fiber elements may be arranged in the circumferential direction, as in FIG 30 shown.

In the embodiment described above, the first light source 326 , the light on one end in the longitudinal direction of the first light guide element 318 radiates, and the first mounting substrate 328 on which the first light source 326 is mounted, between the circumferential directions of the fourth light guide element 324 and the first light guide element 318 be arranged as in 30 shown. The second light source 330 , the light on one end in the longitudinal direction of the second light guide element 320 radiates, and the second mounting substrate 332 on which the second light source 330 is mounted, can between the circumferential directions of the first light guide element 318 and the second optical fiber element 320 be arranged. The third light source 334 , the light on one end in the longitudinal direction of the third light guide element 322 radiates, and the third mounting substrate 336 on which the third light source 334 is mounted, can between the circumferential directions of the second light guide element 320 and the third optical fiber element 322 be arranged. The fourth light source 338 , the light on one end in the longitudinal direction of the fourth light guide element 324 radiates, and the fourth mounting substrate 340 on which the fourth light source 338 is mounted, can between the third light guide element 322 and the fourth optical fiber element 324 be arranged in the circumferential direction.

In the embodiment described above, the light source may be arranged at both ends in the longitudinal direction of the light guide element. In this case, one end face in the longitudinal direction and the other end face in the longitudinal direction of the light guide element act as incident surfaces, through which the light of the light source enters.

In the embodiment described above, the light emitting units 42A . 42B an annular retaining element comprising the rim 26 of the front wheel 14 covering, for example, instead of the first wheel cover 116A and the second wheel cover 116B , The holding member may be any of the light source units 48 . 50 . 52 . 54 , each of the light guide elements 136 . 138 . 140 . 142 , each of the reflective slides 144 . 146 , each of the carrying elements 148 . 150 , each of the translucent covers 152 . 154 . 156 . 158 , each of the fasteners 160 . 162 . 164 . 166 and the wire group 46A hold. The holding element may be formed, the rim 26 completely cover and the spokes 28 partially cover. Alternatively, the holding element may be formed, the rim 26 not cover and the spokes 28 partially cover.

In the embodiment described above, the wire holder, which is the wire group 46A holds, formed by a groove, which is different from that of the third holding portion 128C different. An example of the wire holder is a hook for holding the wire group 46A in the rim coupling section 126 , The wire is between the hook and the rim coupling portion 126 held by the wires of the wire group 46A hooked on the hook to the wire group 46A at the rim coupling section 126 to keep.

In the embodiment described above, as in FIG 31 shown is the second camp 194 be omitted, and the second port 342 between the terminal holding member 272 and the first bearing seat 244 can be a cylindrical, stationary element 344 contact that at the hub shaft 184 is fixed. The second connection 342 includes the first bent portion 346 , the second bent section 348 and the third bent section 350 in the same way as the first bent section 270A , the second curved section 270B and the third bent section 270C of the second connection 270 the embodiment described above. The second connection 342 includes a fourth bent portion 352 , to the hub shaft 184 is bent from the portion extending to an axial side of the third bent portion 350 in the second port 342 extends, and an extending portion 354 extending from the fourth curved section 352 to the hub shaft 184 extends. The extending section 354 includes a moving part 356 which is bent in the axial direction and extends. The moving part 356 contacts the outer peripheral surface of the stationary element 344 , The stationary element 344 is made of metal. The first conductive wire 100A of the seventh wire 100 is with an axial end face of the stationary element 344 connected.

In the embodiment described above, one of the first seat portion 244A or the second seat portion 246 of the first bearing seat 244 from the holder 204 be formed separately.

In the embodiment described above, the hub shaft 184 a plurality of wire receiving sections 186 include.

In the embodiment described above, the inner ring 248 of the first camp 192 not directly on the hub shaft 184 be fixed. One other element may be between the inner ring 248 and the hub shaft 184 be held.

In the embodiment described above, the terminal holding member 272 be arcuate viewed in the axial direction.

In the embodiment described above, the terminal holding member 272 outward in the radial direction from the outer ring 250 of the first camp 192 be spaced. In this case, the first port includes 268 a portion that extends to the radially inner side to the outer ring 250 to contact.

In the embodiment described above, the first port 268 in a removable manner to the terminal holding member 272 be coupled.

In the embodiment described above, the second port 270 on the terminal holding member 272 be fixed for example by welding or an adhesive.

In the embodiment described above, one of the holder may 204 separate element between the holder 204 and the second port 270 are located.

In the embodiment described above, the first port 268 be omitted. In this case, the second conductive wire 88B of the first wire 88 the outer ring 250 of the first camp 192 contact directly.

In the embodiment described above, the second port 270 be omitted. In this case, the second conductive wire 100B of the seventh wire 100 the outer ring 256 of the second camp 194 contact directly.

In the embodiment described above, the terminal 284 attached to the bearing retainer 266 is coupled, be omitted. In this case, the first conductive wire 88A of the first wire 88 the inner ring 248 of the first camp 192 contact directly.

In the embodiment described above, the third bearing 196 the conduction path for one of the first wire 88 or the seventh wire 100 be. In this case, the third camp defines 196 the second power transmission unit. In other words, the second power transmission unit is at least partially in the second bearing seat 208A arranged. The first conductive wire 88A (the first conductive wire 100A ) is with the inner ring 210 of the third camp 196 connected, and the second conductive wire 88B (the second conductive wire 100B ) is directly or indirectly with the outer ring 212 connected. The rolling elements 214 of the third camp 196 connect the inner ring 210 and the outer ring 212 electric.

In the embodiment described above, the converter 82 the controller 44 through the first wheel cover 116A and the second wheel cover 116B being held. In other words, the converter 82 integral with the front wheel 14 rotatable.

In the above-described modifications, the seventh wire 100 from the controller 44 be omitted.

In the modifications described above, one of the first port 268 or the second port 270 be omitted. In this case, the first conductive wire 88A of the first wire 88 with the other from the first port 268 and the second port 270 connected.

In the embodiment described above, at least one of the light emitting units 42A . 42B in the light emitting device 40 of the bicycle include an operation unit that switches between a light emitting state in which each light source is activated and a non-light emitting state in which each light source is deactivated. The control unit 86 the controller 44 can be switched so that the control circuit 56 is turned on and off based on actuation signals of the actuator unit.

In the embodiment described above, the rear wheel 16 instead of the front wheel 14 the hub dynamo 180 include.

In the embodiment described above, one of the first wheel cover 116A and the second wheel cover 116B be omitted from the light source and the light guide element.

In the embodiment described above, one of the light emitting units 42A . 42B be omitted.

Some of the components disclosed in the embodiments (in one or more forms) may be omitted or combined. Therefore, the present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.

LIST OF REFERENCE NUMBERS

L

 light source

LG

 Optical fiber element

LG1

 incident surface

LG2

 reflecting surface

LG3

 Light emitting surface

B

 fastener

R1

 First area

R2

 Second area

R3

 Third area

10

 bicycle

14

 Front wheel (wheel)

16

 Rear wheel

40

 Light emitting device (bicycle light emitting device)

56

 control circuit

58, 70

 First light source

60, 72

 Second light source

62, 74

 First mounting substrate (mounting substrate)

62A, 74A

 One main surface (one surface)

62B, 74B

 Other main area (other area)

64, 76

 Third light source

66, 78

 Fourth light source

68, 80

 Second mounting substrate (mounting substrate)

68A, 80A

 One main surface (one surface)

68B, 80B

 Other main area (other area)

82

 converter

88, 102

 First wire (wire)

90, 104

 Second wire (wire)

92, 106

 Third wire (wire)

94, 108

 Fourth wire (wire)

96, 110

 Fifth wire (wire)

98, 112

 Sixth wire (wire)

100, 114

 Seventh wire (wire)

116A

 First wheel cover (holding element)

116B

 Second wheel cover (holding element)

128C

 Third holding section (wire holder)

132

 Control substrate (substrate of the control circuit)

134

 Carrying wall (control circuit holder)

136

 First light guide element (light guide element)

136A

 First incidence area (incidence area)

136B

 First reflection surface (reflection surface)

136C

 First light emission surface (light emission surface)

136D

 reflection pattern

138

 Second light guide element (light guide element)

138A

 Second incidence area (incidence area)

138B

 Second reflection surface (reflection surface)

138C

 Second light emission surface (light emission surface)

140

 Third light guide element (light guide element)

142

 Fourth light guide element (light guide element)

160

 First fastening element (fastening element)

162

 Second fastening element (fastening element)

164

 Third fastening element (fastening element)

166

 Fourth fastening element (fastening element)

180

 Hub dynamo (power generator)

298

 battery

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 3173794 U [0003]

Claims (27)

A bicycle light emitting device comprising: a light source that is rotatable integrally with a wheel of a bicycle; and a lightguide member that guides light from the light source, wherein the lightguide member is rotatable integrally with the wheel. The bicycle light emitting device according to claim 1, wherein the light guide member includes an incident surface into which light from the light source enters, a reflection surface that reflects the light entering the incident surface, and a light emission surface that faces the reflection surface. A bicycle light emitting device according to claim 1 or 2, wherein said optical fiber element extends in a predetermined direction. A bicycle light emitting device according to any one of claims 1 to 3, wherein the light source is arranged so that an optical axis of the light source and a rotation axis of the wheel extend in different directions. A bicycle light emitting device according to claim 4, wherein the optical axis of the light source is substantially parallel to a direction orthogonal to the rotational axis of the wheel. A bicycle light emitting device according to any one of claims 1 to 5, wherein the optical fiber element comprises a first optical fiber element and a second optical fiber element which is spaced from the first optical fiber element. A bicycle light emitting device according to claim 6, wherein the first conductor member and the second conductor member are arranged in a circumferential direction of the wheel. A bicycle light emitting device according to claim 6 or 7, wherein the light source comprises a first light source and a second light source, and the first light source and the second light source are located between the first light guide element and the second light guide element. The bicycle light emitting device according to claim 8, wherein the first light source and the second light source are located between a first incident surface that is the incident surface of the first optical fiber element and a second incident surface that is the incident surface of the second optical fiber element. A bicycle light emitting device according to claim 9, wherein the first light source is arranged such that an optical axis of the first light source intersects the first incident surface, and the second light source is arranged such that an optical axis of the second light source intersects the second incident surface. The bicycle light emitting device of claim 9, further comprising a mounting substrate located between the first incident surface and the second incident surface, the mounting substrate comprising a surface on which the first light source is mounted and another surface. on which the second light source is mounted. A bicycle light emitting device according to any one of claims 1 to 11, wherein the light guide member has an arcuate or annular shape. A bicycle light emitting device according to any one of claims 2 to 12, wherein the incident surface is provided at only one end in the longitudinal direction of the light guide member. A bicycle light emitting device according to any one of claims 1 to 13, wherein the thickness of the light guide member decreases from the one end in the longitudinal direction to a further end in the longitudinal direction. A bicycle light emitting device according to any one of claims 2 to 14, wherein the reflection surface comprises a reflection pattern, and the reflection pattern has a density distribution that varies in a longitudinal direction of the light guide element. A bicycle light emitting device according to claim 15, wherein the optical waveguide element in the reflection surface comprises a first region located on one side of the one end in the longitudinal direction, a second region located on one side of the other end in the longitudinal direction, and a third region extending between the first region and located in the second area; and the reflection pattern in the third region has a smaller density distribution than the reflection pattern in the first region and the reflection pattern in the second region. A bicycle light emitting device according to any one of claims 1 to 16, further comprising a control circuit capable of supplying power to the light source, the control circuit being integrally rotatable with the wheel. A bicycle light emitting device according to any one of claims 1 to 17, further comprising a holding member capable of Hold light guide element and the light source, wherein the holding member is rotatable integrally with the wheel. The bicycle light emitting device according to claim 18, further comprising a wire that supplies power to the light source, wherein the holding member includes a wire holder that holds the wire. The bicycle light emitting device according to claim 19, wherein the wire holder holds the wire in a circumferential direction of the wheel, and the optical fiber element is coupled to the wire holder so as to overlap the wire when viewed in an axial direction of the wheel. A bicycle light emitting device according to any one of claims 18 to 20, wherein the holding member includes a control circuit holder which holds a substrate of the control circuit in an axial direction of the wheel. A bicycle light emitting device according to any one of claims 18 to 21, wherein the holding member includes a wheel cover which is disc-shaped and covers at least a portion of a side surface of the wheel. The bicycle light emitting device according to any one of claims 18 to 22, further comprising a fixing member fixing the light guide member to the holding member, the fixing member covering the light source. A bicycle light emitting device according to any one of claims 1 to 23, wherein said light source is a light emitting diode. A bicycle light emitting system comprising: the bicycle light emitting device according to any one of claims 1 to 24; and a power generator that generates power when the wheel rotates and supplies the light source with the generated power. The bicycle light emitting system of claim 25, further comprising a converter that converts AC power generated by the power generator into DC power, the converter providing DC power to the light source. A bicycle light emitting system comprising: the bicycle light emitting device according to any one of claims 1 to 24; and a battery that supplies the light source with DC power, the battery being rotatable integrally with the wheel.

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