DE102016012624A1 - bicycle hub - Google Patents

Abstract

To provide a bicycle hub that permits downsizing a structure for detecting a rotational state, a front hub includes a shaft 81, a rotating body 82 rotatable relative to the shaft 81, and a rotation detector 1 detecting rotation of the rotating body 82. The rotation detector 1 includes magnets 3, 4, a magnetic element, a coil wound with respect to the magnetic element, and a magnetic flux induction body. The magnets 3, 4 are respectively magnetized in a direction intersecting a rotation axis of the rotating body 82, and magnetized in the circumferential direction of the rotating body 82 such that the magnetization directions are alternately opposite to each other. The magnetic member extends along the rotation axis and has a magnetization direction reversed in a direction extending along the rotation axis of the rotation body 82 by a magnetic flux formed by some of the magnets 3, 4. When some of the magnets 3, 4 pass through a predetermined position in a rotation path, the magnetic flux induction body induces the magnetic flux to pass through the magnetic element in the direction extending along the rotation axis of the rotation body 82.

Description

FIELD OF THE INVENTION

 The subject matter of the present disclosure relates to a bicycle hub.

BACKGROUND OF THE INVENTION

The Japanese Patent Publication No. 7-229909 discloses a bicycle hub including a hub shaft coupled to a frame of a bicycle, a hub shell rotatable relative to the rotating shaft, and a dynamo housed in the hub shell. The dynamo includes a stator which is fixed to the hub shaft and a rotor which rotates together with the hub shell. The rotational state of the bicycle hub is detected due to the frequency of the AC current (AC) output from the dynamo.

SUMMARY

 There is a need for an improvement in the downsizing of a structure for detecting a rotational state of a bicycle hub.

• (1) Ein erster Aspekt des Gegenstandes nach der vorliegenden Offenbarung beinhaltet eine Fahrradnabe, eine Welle, einen Drehkörper, der bezüglich der Welle drehbar ist, und einen Drehdetektor, der eine Drehung des Drehkörpers detektiert. Der Drehdetektor beinhaltet Magnetfeld ausbildende Abschnitte, die sich in/an dem Drehkörper befinden, ein Magnetelement, das sich innerhalb eines Drehweges der Magnetfeld ausbildenden Abschnitte befindet, eine Spule, welche um das Magnetelement gewickelt ist/wird, und einen Magnetflussinduktionskörper, welcher sich zwischen dem Drehweg und dem Magnetelement befindet. Die Magnetfeld ausbildenden Abschnitte, wobei jeder davon in einer Richtung, die eine Drehachse des Drehkörpers schneidet, magnetisiert ist/wird, sind in einer Umfangsrichtung des Drehkörpers angeordnet, derart, dass die Magnetisierungsrichtungen zueinander abwechselnd entgegengesetzt sind. Das Magnetelement erstreckt sich in einer Richtung, die sich entlang der Drehachse des Drehkörpers erstreckt, und weist eine Magnetisierungsrichtung auf, die in der Richtung, die sich entlang der Drehachse des Drehkörpers erstreckt, durch ein Magnetfeld, das durch zumindest eines von den Magnetfeld ausbildenden Abschnitten ausgebildet ist, umgekehrt bzw. reversiert bzw. umgedreht ist. Wenn der zumindest eine von den Magnetfeld ausbildenden Abschnitten durch eine vorbestimmte Position in dem Drehweg läuft, induziert der Magnetflussinduktionskörper einen Magnetfluss, welcher durch den zumindest einen von dem Magnetfeld ausbildenden Abschnitten ausgebildet ist/wird, um durch das Magnetelement in der Richtung, die sich entlang der Drehachse des Drehkörpers erstreckt, zu laufen.
• (2) In einem zweiten Aspekt des Gegenstandes nach der vorliegenden Offenbarung ist bei einer Fahrradnabe nach dem vorstehenden Aspekt die Welle ausgestaltet, um eine Nabenwelle zu sein, die an einen Rahmen eines Fahrrades gekoppelt sein kann. Der Drehkörper ist ausgestaltet, um eine Nabenhülle zu sein, die bezüglich der Nabenwelle dreht.
• (3) In einem dritten Aspekt des Gegenstandes nach der vorliegenden Offenbarung sind bei einer Fahrradnabe nach einem der vorstehenden Aspekte die Magnetfeld ausbildende Abschnitte an die Nabenhülle gekoppelt.
• (4) In einem vierten Aspekt des Gegenstandes nach der vorliegenden Offenbarung befindet sich bei einer Fahrradnabe nach einem der vorstehenden Aspekte zumindest ein Abschnitt des Drehdetektors zwischen der Nabenwelle und der Nabenhülle.
• (5) In einem fünften Aspekt des Gegenstandes nach der vorliegenden Offenbarung beinhaltet die Nabenhülle eine Innenfläche. Die Nabenwelle ist hohl und beinhaltet ein Loch, gegenüberliegend bzw. gegenüberstehend zu der Innenfläche der Nabenhülle. Der Magnetflussinduktionskörper befindet sich in der Nabenwelle und ist zu den Magnetfeld ausbildenden Abschnitten durch das Loch entgegengesetzt oder zumindest ein Abschnitt des Magnetflussinduktionskörper ist von dem Loch freigelegt und zu den Magnetfeld ausbildenden Abschnitten entgegengesetzt.
• (6) In einem sechsten Aspekt des Gegenstandes nach der vorliegenden Offenbarung ist bei einer Fahrradnabe nach einem der vorstehenden Aspekte die Welle ausgestaltet, um eine Nabenwelle zu sein, die an einen Rahmen eines Fahrrades gekoppelt sein kann. Der Drehkörper ist ausgestaltet, um ein Freilauf zu sein, der sich benachbart zu einer Nabenhülle in einer Axialrichtung befindet und eine Drehung in lediglich eine Richtung an die Nabenhülle überträgt.
• (7) In einem siebten Aspekt des Gegenstandes nach der vorliegenden Offenbarung sind bei einer Fahrradnabe nach einem der vorstehenden Aspekte die Magnetfeld ausbildenden Abschnitte an den Freilauf gekoppelt.
• (8) In einem achten Aspekt des Gegenstandes nach der vorliegenden Offenbarung befindet sich bei einer Fahrradnabe nach einem der vorstehenden Aspekte zumindest ein Abschnitt des Drehdetektors zwischen der Nabenwelle und dem Freilauf.
• (9) In einem neunten Aspekt des Gegenstandes nach der vorliegenden Offenbarung beinhaltet bei einer Fahrradnabe nach einem der vorstehenden Aspekte der Freilauf eine Innenfläche. Die Nabenwelle ist hohl und beinhaltet ein Loch, gegenüberliegend bzw. gegenüberstehend zu der Innenfläche des Freilaufes. Der Magnetflussinduktionskörper befindet sich in der Nabenwelle und ist zu den Magnetfeld ausbildenden Abschnitten durch das Loch entgegengesetzt oder zumindest ein Abschnitt von dem Magnetflussinduktionskörper ist von dem Loch freigelegt und zu den Magnetfeld ausbildenden Abschnitten entgegengesetzt.
• (10) In einem zehnten Aspekt des Gegenstandes nach der vorliegenden Offenbarung, bei einer Fahrradnabe nach einem der vorstehenden Aspekte, wenn einer oder zwei von den Magnetfeld ausbildenden Abschnitten, bei welchen die Magnetisierungsrichtungen zueinander entgegengesetzt sind, durch eine erste vorbestimmte Position in dem Drehweg läuft und der andere von den zwei der Magnetfeld ausbildenden Abschnitte gleichzeitig durch eine zweite vorbestimmte Position in dem Drehweg läuft, induziert der Magnetflussinduktionskörper einen Magnetfluss, der aus dem einen der Magnetfeld ausbildenden Abschnitte austritt und den anderen von den Magnetfeld ausbildenden Abschnitten betritt, derart, dass der Magnetfluss durch das Magnetelement in der Richtung, die sich entlang der Drehachse des Drehkörpers erstreckt, läuft.
• (11) In einem elften Aspekt des Gegenstandes nach der vorliegenden Offenbarung beinhaltet bei einer Fahrradnabe nach einem der vorstehenden Aspekte der Magnetflussinduktionskörper zwei Jochstücke bzw. Gabelstücke bzw. Bügelstücke. Die zwei Jochstücke sind voneinander separiert bzw. getrennt und zueinander in der Richtung, die sich entlang der Drehachse des Drehkörpers erstreckt, entgegengesetzt bzw. gegenüberliegend bzw. gegenüberstehend. Jedes von den zwei Jochstücken beinhaltet einen Vorsprung, der hin zu dem Drehweg vorspringt. Wenn einer von zwei der Magnetfeld ausbildenden Abschnitte, bei welchen die Magnetisierungsrichtungen zueinander entgegengesetzt sind, sich benachbart bzw. nächstliegend bzw. proximal zu dem Vorsprung von einem der zwei Jochstücken befindet, befindet sich der andere von den zwei der Magnetfeld ausbildenden Abschnitte benachbart bzw. nächstliegend bzw. proximal zu dem Vorsprung von dem anderen der zwei Jochstücke.
• (12) In einem zwölften Aspekt des Gegenstandes nach der vorliegenden Offenbarung befindet sich bei einer Fahrradnabe nach einem der vorstehenden Aspekte einer von den zwei Jochstücken an einer Position entsprechend zu einem Ende des Magnetelements. Das andere von den zwei Jochstücken befindet sich an einer Position entsprechend zu dem anderen Ende des Magnetfelds.
• (13) In einem dreizehnten Aspekt des Gegenstandes nach der vorliegenden Offenbarung ist bei einer Fahrradnabe nach einem der vorstehenden Aspekte jedes von den zwei Jochstücken durch ein plattenförmiges Glied ausgebildet. Das Glied biegt sich in Übereinstimmung mit einem äußersten Umfang der Spule, die um das Magnetelement gewickelt ist.
• (14) In einem vierzehnten Aspekt des Gegenstandes nach der vorliegenden Offenbarung ist bei einer Fahrradnabe nach einem der vorstehenden Aspekte jedes von den zwei Jochstücken durch ein plattenförmiges Glied ausgebildet. Das Glied erstreckt sich von einer Position entsprechend zu einem Abschnitt des Magnetelements, bezüglich dessen die Spule gewickelt ist, zu einer Position entsprechend einem Abschnitt des Magnetelements, das von der Spule frei ist, und dann biegt und erstreckt es sich, um zu dem Magnetelement benachbart bzw. nächstliegend bzw. proximal zu sein.
• (15) In einem fünfzehnten Aspekt des Gegenstandes nach der vorliegenden Offenbarung, bei einer Fahrradnabe nach einem der vorstehenden Aspekte, wenn eines von den mangelnder Abschnitten durch eine vorbestimmte Position in dem Drehweg läuft, induziert der Magnetflussinduktionskörper einen Magnetfluss, der aus einer Fläche des Magnetfeld ausbildenden Abschnittes austritt und eine andere Fläche des Magnetfeld ausbildenden Abschnittes hinsichtlich einer Drehrichtung des Drehkörpers betritt, derart, dass der Magnetfluss durch das Magnetelement in der Richtung, die sich entlang der Drehachse des Drehkörpers erstreckt, läuft.
• (16) In einem sechzehnten Aspekt des Gegenstandes nach der vorliegenden Offenbarung beinhaltet bei einer Fahrradnabe nach einem der vorstehenden Aspekte jeder von den Magnetfeld ausbildenden Abschnitten ein erstes Magnetfeld ausbildendes Stück und ein zweites Magnetfeld ausbildendes Stück, bei welchen jedes in eine Richtung, die die Drehachse des Drehkörpers schneidet, magnetisiert ist/wird. Das erste Magnetfeld ausbildende Stück und das zweite Magnetfeld ausbildende Stück sind in der Richtung, die sich entlang der Drehachse des Drehkörpers erstreckt, angeordnet, derart, dass die Magnetisierungsrichtungen zueinander entgegengesetzt sind. Die Magnetfeld ausbildenden Abschnitte sind in der Umfangsrichtung des Drehkörpers angeordnet, derart, dass die Magnetisierungsrichtungen des ersten Magnetfeld ausbildenden Stückes abwechselnd zueinander in der Umfangsrichtung des Drehkörpers entgegengesetzt sind, und derart, dass die Magnetisierungsrichtungen des zweiten Magnetfeld ausbildenden Stückes abwechselnd zueinander in der Umfangsrichtung des Drehkörpers entgegengesetzt sind. Wenn einer von den Magnetfeld ausbildenden Abschnitten durch eine vorbestimmte Position in dem Drehweg läuft, induziert der Magnetflussinduktionskörper einen Magnetfluss, der aus einem von dem ersten Magnetfeld ausbildenden Stück und dem zweiten Magnetfeld ausbildenden Stück des Magnetfeld ausbildenden Abschnittes austritt und das andere von dem ersten Magnetfeld ausbildenden Stück und dem zweiten Magnetfeld ausbildenden Stück des Magnetfeld ausbildenden Abschnittes betritt, derart, dass der Magnetfluss durch das Magnetelement in der Richtung, die sich entlang des Drehachse des Drehkörpers erstreckt, läuft.
• (17) In einem siebzehnten Aspekt des Gegenstandes nach der vorliegenden Offenbarung ist bei einer Fahrradnabe nach einem der vorstehenden Aspekte das Magnetelement ein großes Barkhausen-Element.

It is an object of the subject matter of the present disclosure to provide a bicycle hub that allows downsizing of a structure for detecting a rotational state.

• (1) A first aspect of the article according to the present disclosure includes a bicycle hub, a shaft, a rotary body that is rotatable with respect to the shaft, and a rotation detector that detects rotation of the rotary body. The rotation detector includes magnetic field forming portions located in / on the rotary body, a magnetic member located within a rotational path of the magnetic field forming portions, a coil wound around the magnetic member, and a magnetic flux induction body extending between the magnetic field Turning and the magnetic element is located. The magnetic field forming portions, each of which is magnetized in a direction intersecting a rotation axis of the rotary body, are arranged in a circumferential direction of the rotary body such that the magnetization directions are alternately opposite to each other. The magnetic member extends in a direction extending along the rotational axis of the rotary body, and has a magnetization direction in the direction extending along the rotational axis of the rotary body through a magnetic field passing through at least one of the magnetic field forming portions is formed, is reversed or reversed or reversed. When the at least one magnetic field forming portion passes through a predetermined position in the rotation path, the magnetic flux induction body induces a magnetic flux formed through the at least one magnetic field forming portion to pass through the magnetic member in the direction along the axis of rotation of the rotary body extends to run.
• (2) In a second aspect of the article according to the present disclosure, in a bicycle hub according to the above aspect, the shaft is configured to be a hub shaft that may be coupled to a frame of a bicycle. The rotary body is configured to be a hub shell rotating with respect to the hub shaft.
• (3) In a third aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, the magnetic field forming portions are coupled to the hub shell.
• (4) In a fourth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, at least a portion of the rotation detector is located between the hub shaft and the hub shell.
• (5) In a fifth aspect of the article according to the present disclosure, the hub shell includes an inner surface. The hub shaft is hollow and includes a hole opposite to the inner surface of the hub shell. The magnetic flux induction body is located in the hub shaft and is opposite to the magnetic field forming portions through the hole or at least a portion of the magnetic flux induction body is exposed from the hole and opposite to the magnetic field forming portions.
• (6) In a sixth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, the shaft is configured to be a hub shaft that may be coupled to a frame of a bicycle. The rotary body is configured to be a freewheel located adjacent to a hub shell in an axial direction and transmitting rotation in only one direction to the hub shell.
• (7) In a seventh aspect of the article of the present disclosure, in a bicycle hub according to any one of the above aspects, the magnetic field forming portions are coupled to the freewheel.
• (8) In an eighth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, at least a portion of the Rotary detector between the hub shaft and the freewheel.
• (9) In a ninth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, the freewheel includes an inner surface. The hub shaft is hollow and includes a hole opposite to the inner surface of the freewheel. The magnetic flux induction body is located in the hub shaft and is opposite to the magnetic field forming portions through the hole or at least a portion of the magnetic flux induction body is exposed from the hole and opposite to the magnetic field forming portions.
• (10) In a tenth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, when one or two magnetic field forming portions in which the magnetization directions are opposite each other passes through a first predetermined position in the rotation path and the other of the two magnetic field forming portions simultaneously passes through a second predetermined position in the rotation path, the magnetic flux induction body induces a magnetic flux exiting the one magnetic field forming portion and entering the other magnetic field forming portions such that the magnetic flux inducing portion Magnetic flux through the magnetic element in the direction that extends along the axis of rotation of the rotary body runs.
• (11) In an eleventh aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, the magnetic flux induction body includes two yoke pieces. The two yoke pieces are separated from each other and opposed to each other in the direction extending along the rotation axis of the rotary body. Each of the two yoke pieces includes a projection projecting toward the turning path. When one of two magnetic field forming portions, in which the magnetization directions are opposite to each other, is proximal to the protrusion of one of the two yoke pieces, the other of the two magnetic field forming portions is adjacent or proximal to the projection of the other of the two Jochstücke.
• (12) In a twelfth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, one of the two yoke pieces is located at a position corresponding to one end of the magnetic member. The other of the two yoke pieces is located at a position corresponding to the other end of the magnetic field.
• (13) In a thirteenth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, each of the two yoke pieces is formed by a plate-shaped member. The member bends in accordance with an outermost circumference of the coil wound around the magnetic element.
• (14) In a fourteenth aspect of the article of the present disclosure, in a bicycle hub according to any one of the above aspects, each of the two yoke pieces is formed by a plate-shaped member. The member extends from a position corresponding to a portion of the magnetic member with respect to which the coil is wound to a position corresponding to a portion of the magnetic member which is free from the coil, and then bends and extends to adjoin the magnetic member or proximate or proximal.
• (15) In a fifteenth aspect of the article of the present disclosure, in a bicycle hub according to any one of the above aspects, when one of the missing portions passes through a predetermined position in the rotation path, the magnetic flux induction body induces a magnetic flux consisting of an area of the magnetic field emerges from the forming portion and enters another surface of the magnetic field forming portion with respect to a rotational direction of the rotary body, such that the magnetic flux passes through the magnetic element in the direction extending along the rotational axis of the rotary body.
• (16) In a sixteenth aspect of the article according to the present disclosure, in a bicycle hub according to any one of the above aspects, each of the magnetic field forming portions includes a first magnetic field forming piece and a second magnetic field forming piece, each in a direction corresponding to the rotational axis of the rotating body cuts / becomes magnetized. The first magnetic field forming piece and the second magnetic field forming piece are arranged in the direction extending along the rotation axis of the rotary body, such that the magnetization directions are opposite to each other. The magnetic field forming portions are arranged in the circumferential direction of the rotary body such that the magnetization directions of the first magnetic field forming piece are alternately opposite to each other in the circumferential direction of the rotary body, and such that the magnetization directions of the second magnetic field forming piece are alternately to each other in the circumferential direction of the rotating body are opposite. When one of the magnetic field forming portions passes through a predetermined position in the rotation path, the magnetic flux induction body induces a magnetic flux exiting from a first magnetic field forming piece and the second magnetic field forming magnetic field forming portion and the other from the first magnetic field Piece and second magnetic field forming portion of the magnetic field forming portion enters, such that the magnetic flux passes through the magnetic element in the direction that extends along the axis of rotation of the rotary body runs.
• (17) In a seventeenth aspect of the article of the present disclosure, in a bicycle hub according to any one of the above aspects, the magnetic member is a large Barkhausen member.

 The above bicycle hub allows downsizing of the structure for detecting a rotational state.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is a side view of a bicycle that includes a first embodiment of a bicycle hub.

2 is a partial cross-sectional view of the bicycle hub shown in FIG 1 ,

3 is a cross-sectional view along the line D3-D3 in 2 ,

4 FIG. 15 is a perspective view illustrating a detection unit of a rotation detector shown in FIG 3 ,

5 is a perspective view of a detecting element and a yoke shown in FIG 4 ,

6 is a side view of the detecting element and the yoke shown in FIG 5 ,

7 is a side view of the detecting element and the yoke shown in FIG 5 ,

8th FIG. 12 is a schematic diagram of the positional relationship among the magnets, the detecting element and the yoke of the rotary detector 3 ,

9 Fig. 12 is a schematic diagram of the positional relationship among the magnets, a detecting element and a yoke of a rotary detector in another embodiment of a bicycle hub.

10 is a side view of a rotary detector includes in a second embodiment of a bicycle hub.

11 is a perspective view of the rotary detector shown in FIG 10 ,

12 is a side view of a rotary detector includes in a third embodiment of a bicycle hub.

13 is a perspective view of the rotary detector shown in FIG 12 ,

14 Figure 4 is a partial cross-sectional view illustrating a fourth embodiment of a bicycle hub.

15 Figure 11 is a partial cross-sectional view illustrating a fifth embodiment of a bicycle hub.

DESCRIPTION OF THE EMBODIMENTS

 First embodiment

The structure of a bicycle 60 that has a front hub 80 , which serves as a bicycle hub, will now be described with reference to FIGS 1 described. The bike 60 includes a frame 61 , a handlebar 62 , a front wheel 63 , a rear wheel 64 and a drive mechanism 65 , The front wheel 63 includes the front hub 80 , The rear wheel 64 includes a rear hub 66 ,

The drive mechanism 65 includes left and right crank arms 67 , a crankshaft 68 , left and right pedals 69 , a front sprocket 70 , a rear sprocket 71 and a chain 72 , The left and right crank arms 67 are rotatable on the frame 61 through the single crankshaft 68 coupled. The pedals 69 are on the crank arms 67 coupled and rotatable with respect to a pedal axle.

The front sprocket 70 is to the crankshaft 68 coupled. The front sprocket 70 is coaxial with the crankshaft 68 coupled, such that the front sprocket 70 not relative to the crankshaft 68 rotates.

The rear sprocket 71 is at the rear hub 66 coupled and with respect to an axis 64A the rear wheel 64 rotatable. The chain 72 runs around the front sprocket 70 and the rear sprocket 71 , The rear hub 66 is at the spokes 64B the rear wheel 64 coupled.

When a human driving force on the pedals 69 is applied to the crank arms 67 To turn, turn the front sprocket 70 , the Chain 72 and the rear sprocket 71 the rear hub 66 , This turns the rear wheel 64 , The front hub 80 is made of spokes 63A of the front wheel 63 supported.

As in 2 shown, includes the front hub 80 a wave 81 , a rotating body 82 , which with respect to the axis 81 is rotatable, and a rotation detector 1 , which rotation of the rotary body 82 detected. The front hub 80 preferably includes two roller bearings 83 ,

The wave 81 is designed to be a hub shaft attached to the frame 61 of the bicycle 60 (With reference to 1 ) can be coupled. The wave 81 is on the frame 61 coupled and unable or unable to turn. The wave 81 includes two axial ends passing through the frame 61 be supported and attached to the frame 61 are coupled by removable mooring members (not shown). The mooring members are, for example, nuts and bolts.

The rotary body 82 is configured to be a hub shell, with respect to the shaft 81 rotates. The rotary body 82 is about the wave 81 rotatable with respect to a rotation axis X. The rotary body 82 includes an inner surface, the recesses 82A includes in which components of the rotary detector 1 are / are coupled. The rotary body 82 includes two ends, which in a direction in which the shaft 81 of the rotary body 82 extends, are arranged. The circumference of each of the two ends includes spoke attachment portions 82B to which the spokes 83A (With reference to 1 ) are / are coupled.

Each one of the roller bearings 83 includes an outer ring 83A , which on the rotary body 82 coupled, an inner ring 83B , which is connected to the shaft 81 coupled, and rolling elements 83C passing through the outer ring 83A and the inner ring 83B be supported. The roller bearings 83 are mutually in the direction in which the shaft 81 extends, separates.

As in 3 represented, is the rotation detector 1 between the wave 81 and the rotary body 82 , The rotation detector 1 includes a support body 11 that by the shaft 81 is / is supported. The supporting body 11 is on a peripheral surface of the shaft 81 by a fixing member 6 fixed. magnets 3 and magnets 4 , which serve as magnetic field forming pieces, are at the recesses 82A of the rotary body 82 coupled. A detection unit 7 is on the support body 11 fixed. The detection unit 7 includes a detection element 14 which is a magnetic element 15 and a coil 16 includes, and a yoke 21 or yoke, which is referred to as a magnetic flux induction body (refer to FIG 4 ) serves. If the rotary body 82 relative to the support body 11 turns, turn the magnets 3 and the magnets 4 relative to the detecting element 14 and the yoke 21 , Consequently, the magnets change 3 and the magnets 4 the magnetic field acting on the magnetic element 15 is / is. This returns a magnetization direction of the magnetic element 15 around. Accordingly, the coil gives 16 a pulse or pulse.

As described above, when the rotation detector 1 on a detected object, which is the shaft 81 includes, which is a non-rotary section, is applied, and the rotary body 82 which is relative to the shaft 81 turns, is the support body 11 to the wave 81 fixed and the magnets 3 and the magnets 4 are at the rotary body 82 fixed. Consequently, the rotation detector detects 1 a rotation of the rotating body 82 relative to the support body 11 ,

Alternatively, the magnets 3 and the magnets 4 to the wave 81 be fixed / when the support body 11 to the rotary body 82 is / is fixed. In this case, the rotation of the support body 11 relative to the rotary body 82 detected. In each embodiment, a rotation of the rotary body 82 relative to the support body 11 detected.

As in 3 shown are the recesses 82A to which the magnets 3 and the magnets 4 are coupled, in an inner surface of the rotary body 82 in the circumferential direction of the rotary body 82 arranged.

The magnets 3 and the magnets 4 which are plate-shaped permanent magnets extend in a direction parallel to the rotation axis X, which is an example of a direction extending along the rotation axis X (refer to FIG 2 ). The magnets 3 and the magnets 4 are / are each magnetized in one direction, which is the axis of rotation X of the rotating body 82 cuts, and are in the circumferential direction of the rotating body 82 arranged such that the magnetization directions are alternately opposite to each other. In the present embodiment, the magnets are / are 3 and the magnets 4 each in a direction perpendicular to the axis of rotation X of the rotary body 82 magnetized.

Every magnet 3 includes a circumferential inner surface having a north pole and a peripheral outer surface having a south pole. Every magnet 4 includes a circumferential inner surface having a south pole and a peripheral outer surface having a north pole. The number of magnets 3 must be the same as the number of magnets 4 , However, as long as this condition is met, the number of magnets is 3 and the number of magnets 4 not limited. If the rotary body 82 turns, the magnets move 3 and the magnets 4 along a turning path L drawn as a circular double-dashed line with the axis of rotation X in the center.

The structure that holds the magnet 3 and the magnet 4 arranged in the rotary body 82 can be realized, for example, by magnetizing a plurality of portions of a tubular member formed of a hard magnetic material to form the magnetic field forming portions in the member. More specifically, the tubular member formed of the hard magnetic material includes magnetic field forming portions magnetized in the directions perpendicular to the axis and arranged in the circumferential direction of the member such that the magnetization directions are alternately opposite to each other , Then, the member becomes an inner periphery of the rotary body 82 coupled. Alternatively, the rotary body 82 may be formed of a hard magnetic material including such magnetic field forming portions.

As in 4 shown, includes the detection unit 7 the support body 11 having the shape of a tube in which an arcuate portion is cut away. The supporting body 11 is formed of a plastic or resin or the like. A substrate 12 or carrier and a housing 13 are to the support body 11 fixed. The detection element 14 , the yoke 21 and the two connections 17 are attached to the case 13 fixed. More specifically, the support body includes 11 an inner surface including Trägerstütznuten 11A , The carrier support grooves 11A stand / get to the edges of the carrier 11 engaged. In addition, the inner surface of the support body includes 11 Gehäusestütznuten 11B , The housing 13 includes support projections 13A , which with the Gehäusestütznuten 11B engage / arrive. The shape or shape of the support body 11 is not limited to the above shape, as long as the carrier 12 and the case 13 can be fixed.

The 5 to 7 make the detection element 14 and the yoke 21 dar. The 8th shows the magnets 3 and the magnets 4 together with the detection element 14 and the yoke 21 ,

The 5 shows the detection element 14 that is in the case 13 (with reference to 4 ) is located. The detection element 14 detects the rotation of the rotating body 82 relative to the support body 11 due to a magnetic field caused by the magnets 3 and the magnets 4 is trained. The detection element 14 is located within the rotary path L of the magnets 3 and the magnet 4 , The detection element 14 is / is by winding the coil 16 with respect to or around the magnetic element 15 educated.

The magnetic element 15 produces a big Barkhausen effect. The magnetic element 15 For example, a wire of a composite magnetic element having uni-axial anisotropy, which in the Japanese Patent Publication No. 2001-194182 is described. The magnetic element 15 extends parallel to the axis of rotation X of the rotating body 82 , As described in the above publication, the composite magnetic member is magnetized in a direction in which the composite magnetic member 15 extends. Consequently, the magnetization direction of the magnetic element is 15 parallel to the axis of rotation X of the rotating body 82 ,

When a magnetic field on the magnetic element 15 toward a side in the direction in which the magnetic field extends, namely the direction A shown in FIG 5 is applied corresponds to the magnetization direction of the magnetic element 15 the direction A. When the magnetic field on the magnetic element 15 toward the other side in the direction in which the magnetic element 15 extends, namely the direction B shown in 5 is applied corresponds to the magnetization direction of the magnetic element 15 the direction B. The magnetic field applied to the magnetic element 15 is applied by the magnets 3 , the magnet 4 and the yoke 21 trained and described later. A change in the direction of the magnetic field acting on the magnetic element 15 is applied from the direction A to the direction B or from the direction B to the direction A, the magnetization direction of the magnetic element returns 15 around. The magnetization direction of the magnetic element 15 reverses immediately or immediately due to the large Barkhausen effect. As a result, current flows directly to the coil 16 due to the electromagnetic induction, and the coil 16 gives an impulse. The pulse output from the coil 16 can from the connections 17 (with reference to 4 ).

The yoke 21 is located in the housing 13 (with reference to 4 ). The yoke 21 is located between the detection element 14 and the turning path L (refer to FIG 3 ) of the magnets 3 and the magnet 4 , The yoke 21 serves to cause a magnetic flux passing through one of the magnets 3 and one of the magnets 4 which are adjacent to each other in the circumferential direction of the rotary body 82 are to induce this through the magnetic element 15 to go through in the extension direction.

The yoke 21 includes two yoke pieces 22 . 23 , The yoke pieces 22 . 23 are each from one soft magnetic material, such as iron formed. The yoke pieces 22 . 23 are mutually in the direction parallel to the rotational axis X of the rotary body 82 separated. More specific is the yoke piece 22 at a position corresponding to one end of the magnetic element 15 , The yoke piece 23 is at a position corresponding to the other end of the magnetic element 15 , The yoke pieces 22 . 23 are located at a position corresponding to an intermediate portion of the magnetic element 15 in the extension direction. The yoke pieces 22 . 23 are adjacent to or closest to the coil 16 which are around the magnetic element 15 is wound, however, touch the coil 16 Not.

The yoke piece 22 includes a plate-shaped base 24 , a side wall 26 which by bending one end of the base 24 is / is trained, and a projection 28 which is from the base 24 projects. The yoke piece 23 is different from the yoke piece 22 in the position and direction. However, in the same way as the yoke piece 22 , includes the yoke piece 23 One Base 25 , a side wall 27 and a lead 29 ,

The base 24 of the yoke piece 22 is along the outermost circumference of the coil 16 , which with respect to or around the magnetic element 15 is wrapped, bent. Such a bending of the base 24 increases the area of a surface portion of the base 24 leading to the magnetic element 15 is opposite and to the magnetic element 15 is adjacent. The base 25 of the yoke piece 23 is bent in the same way.

As in 7 shown includes the base 24 of the yoke piece 22 an end surface 24A that to the base 25 of the yoke piece 23 is opposite or opposite. Also includes the base 25 of the yoke piece 23 an end surface 25A that to the base 24 of the yoke piece 22 opposite or opposite. The endface 24A and the endface 25A are parallel to each other.

As in 6 shown, the base extends 24 of the yoke piece 22 from a position closer to an intermediate portion, with respect to the extension direction, of the magnetic member 15 around which the coil 16 is wound to a position near one end of the magnetic member 15 that is free from the coil 16 is, in a direction parallel to the extension direction of the magnetic element 15 , Then the base bends 24 and extends in a direction which is the extension direction of the magnetic element 15 cuts (eg orthogonal) to adjacent to the magnetic element 15 to be. The section that points in the direction of the extension direction of the magnetic element 15 cuts, is bent, is the sidewall 26 , The side wall 26 includes an end that is closer to the magnetic element 15 located as other sections of the Jochstückes 22 , The side wall 27 of the yoke piece 23 is designed in the same way.

As in 8th shown, the projections jump 28 . 29 towards the turning path L from the faces of the respective bases 24 . 25 leading to the rotational path L of the magnets 3 and the magnets 4 are opposite, before. The rotational path L includes a magnetic field application position C and a magnetic field application position D.

The magnetic field application position C and the magnetic field application position D are in accordance with the distance between adjacent magnets 3 and the magnet 4 in the circumferential direction of the rotary body 82 set. The lead 28 of the yoke piece 22 advances toward the magnetic field application position C. The lead 29 of the yoke piece 23 advances toward the magnetic field application position D.

The lead 28 of the yoke piece 22 includes a projection end that is adjacent to, but not in contact with, a magnet 3 or a magnet 4 located when the magnet 3 or the magnet 4 is located at the magnetic field application position C. In the same way, the lead includes 29 of the yoke piece 23 a projection end that is adjacent to, but not in contact with, a magnet 3 or a magnet 4 located when the magnet 3 or the magnet 4 is located at the magnetic field application position D. The projections 28 . 29 are from the support body 11 exposed to the outside.

The lead 28 is formed by connecting or engaging a block-shaped member formed of a soft magnetic material with the plate-shaped base formed of a soft magnetic material. The lead 29 is formed in the same way. Instead of a separate link to the base 24 . 25 To couple, the projections can 28 . 29 by bending a section of each from the base 24 . 25 be formed or integral with the base 24 . 25 each be formed.

The operation of the front hub 80 will now be with reference to the 1 . 3 and 8th described.

If the front wheel 63 rotates forward, the rotating body rotates 82 in the clockwise direction relative to the support body 11 , Accordingly, the magnets rotate 3 and the magnets 4 with respect to the detection unit 7 in the clockwise direction. If one of the magnets 3 passes through the magnetic field application position C, the magnet is running 4 , which adjacent to the magnet 3 in the clockwise direction, simultaneously through the magnetic field application position D. When one of the magnets 3 is located at the magnetic field application position C, the magnet is located 3 adjacent to the projection end of the projection 28 of the yoke piece 22 , Also, if the magnet 4 that is adjacent to the magnet 3 is in the clockwise direction, is located at the magnetic field application position D, the magnet is located 4 adjacent to the projection end of the projection 29 of the yoke piece 23 , As described above, when the magnet 3 and the magnet 4 at the same time adjacent to the respective projections 28 . 29 are located, inducing the yoke 21 the magnetic flux coming out of the magnet 3 exit and into the magnet 4 enters to pass through the magnetic element 15 to flow in the extension direction. This brings the magnetic field generated by the magnet 3 and the magnet 4 is formed on the magnetic field 15 in direction A. In the 6 to 8th show a route P11, a path P12 and a path 13 , which are indicated by the arrows, the path or path of the magnetic flux. When the magnetization direction of the magnetic element 15 corresponds to the direction B, the magnetization direction of the magnetic element 15 reversed and changed to the direction A. The sink 16 outputs a pulse corresponding to the inversion of the magnetization direction.

Subsequently or subsequently, when the rotary body 82 rotates in the clockwise direction by a predetermined angle, the magnet moves 3 to the magnetic field application position D from the magnetic field application position C and becomes the projection end of the projection 29 of the yoke piece 23 adjacent. At the same time the magnet reaches 4 that is adjacent to the magnet 4 is in the opposite clockwise direction, the magnetic field application position C and becomes the projection end of the projection 28 of the yoke piece 22 adjacent. As described above, when the magnet 3 and the magnet 4 at the same time adjacent to the projection 29 and the lead 28 are located, inducing the yoke 21 the magnetic flux coming out of the magnet 3 exit and into the magnet 4 enters to pass through the magnetic element 15 to flow or run in the extension direction. The magnetic field caused by the magnet 3 and the magnet 4 is formed on the magnetic element 15 applied in the direction B. This reverses the magnetization direction of the magnetic element 15 in direction B from direction A. The sink 16 outputs a pulse corresponding to the inversion of the magnetization direction. For example, if the rotary body 82 continues to turn in the clockwise direction whenever the rotating body 82 rotates by the predetermined angle, the magnetization direction of the magnetic element is reversed 15 around and the coil 16 gives an impulse. This is the same when the rotary body 82 turns in the opposite clockwise direction.

• (1) Die Struktur zum Detektieren des Drehzustandes kann im Vergleich zum Stand der Technik, in welchem ein Dynamo den Drehzustand detektiert, verkleinert werden.
• (2) Das Joch 21 induziert den Magnetfluss des Magnetfelds, welcher durch den Magnet 3 und den Magnet 4, die in den Richtungen orthogonal zu der Drehachse X des Drehkörpers 82 magnetisiert sind/werden und unterschiedliche Magnetisierungsrichtungen aufweisen, ausgebildet wird, um durch das Magnetelement 15 in der Verlängerungsrichtung zu fließen bzw. zu laufen. Folglich, selbst wenn der Abstand zwischen dem Magnet 3 und dem Magnet 4 in der Umfangsrichtung gering ist, wird ein Magnetfluss zwischen dem Magnet 3 und dem Magnet 4 konzentriert, um durch das Magnetelement 15 in der Verlängerungsrichtung zu fließen bzw. zu laufen. Dies kehrt geeignet die Magnetisierungsrichtung des Magnetelements 15 um. Spezifischer sind jeweils die Magneten 3 und die Magneten 4 in einer Richtung magnetisiert, die die Drehachse X des Drehkörpers 82 schneidet. Folglich, bei benachbarten von den Magneten 3 und den Magneten 4 in der Umfangsrichtung des Drehkörpers 82, ist die Fläche des Magnets 3 aufweisend einen Nordpol zu der Fläche des Magnets 4 aufweisend einen Südpol nicht entgegengesetzt. Dies verringert die Dichte des Magnetflusses, der durch den kürzesten Weg bzw. Pfad läuft, welcher linear den Nordpol des Magnets 3 und den Südpol des Magnets 4, die umfänglich zueinander benachbart sind, verbindet, selbst wenn der Abstand zwischen dem Magnet 3 und dem Magnet 4 in der Umfangsrichtung gering ist. Dies erlaubt es, dass die Fahrgeschwindigkeit des Fahrrades 60 genau detektiert werden kann, aufgrund der Drehgeschwindigkeit des Drehkörpers 82.
• (3) Das Joch 21 induziert den Magnetfluss, welcher durch den Magnet 3 und den Magnet 4 ausgebildet wird, um durch das Magnetelement 15 in der Verlängerungsrichtung zu fließen bzw. zu laufen. Folglich, selbst wenn der Magnet 3 und der Magnet 4 ausgebildet sind, um in eine Richtung, die die Drehachse X des Drehkörpers 82 schneidet, magnetisiert zu sein/werden, wird der Magnetfluss, welcher durch den Magnet 3 und den Magnet 4 ausgebildet wird, konzentriert, um durch das Magnetelement 15 in der Verlängerungsrichtung zu fließen bzw. zu laufen. Dies erhöht die Dichte des Magnetflusses, der durch das Magnetelement 15 in der Verlängerungsrichtung läuft. Dementsprechend, selbst wenn der Abstand zwischen dem Magnet 3 und dem Magnet 4 in der Umfangsrichtung gering ist, wird die Magnetisierungsrichtung des Magnetelements 15 entsprechend durch das Magnetfeld, welches durch den Magnet 3 und den Magnet 4 ausgebildet ist, umgekehrt. Dies erlaubt eine Verkleinerung des Drehdetektors 1 und eine Verbesserung der Auflösung der Drehdetektion.
• (4) Das Joch 21 ist ausgestaltet, um den Magnetfluss zu induzieren, der aus dem Magnet 3 austritt und in den Magnet 4 eintritt, um durch das Magnetelement 15 in der Verlängerungsrichtung zu fließen bzw. zu laufen. Folglich wird die Struktur des Joches 21 vereinfacht. Dies erhöht die Dichte Magnetflusses, der durch das Magnetelement 15 in der Verlängerungsrichtung läuft und kehrt die Magnetisierungsrichtung des Magnetelements 15 in einer sicheren Weise um. Spezifischer, da der Magnet 3 und der Magnet 4 entgegengesetzte Magnetisierungsrichtungen in der Umfangsrichtung des Drehkörpers 82 aufweisen, sind die Fläche des Magnets 3 aufweisend einen Nordpol und die Fläche des Magnets 4 aufweisend einen Südpol zu dem Inneren des Drehweges L entgegengesetzt. Zusätzlich befindet sich das Magnetelement 15 innerhalb des Drehweges L. Dies verkürzt den Weg bzw. Pfad des Magnetflusses, der aus der Fläche des Magnets 3 aufweisend einen Nordpol austritt, durch das Magnetelement 15 in die Verlängerungsrichtung fließt und in die Fläche des Magnetes 4 aufweisend einen Südpol eintritt und vereinfacht die Gestalt des Weges bzw. Pfades. Folglich wird die Struktur des Joches 21, welches den Magnetfluss in einen solchen vereinfachten und kurzen Weg bzw. Pfad induziert, vereinfacht. Zusätzlich wird der Magnetfluss leicht konzentriert auf dem einfachen und kurzen Weg bzw. Pfad. Dies erhöht die Dichte des Magnetflusses, der durch den Weg bzw. Pfad fließt bzw. läuft.
• (5) Die Jochstücke 22, 23 beinhalten die Vorsprünge 28, 29. Die Vorsprungsenden der Vorsprünge 28, 29 befinden sich benachbart bzw. nächstliegend zu dem Magnet 3 oder dem Magnet 4, der durch die Magnetfeldaufbringungsposition C oder die Magnetfeldaufbringungsposition D läuft. Dies verkürzt den Abstand zwischen jedem von der Magnet 3 und dem Magnet 4 und jedem von den Vorsprüngen 28, 29. Dies erlaubt es dem Magnetfluss aus dem Magnet 3 auszutreten und angemessen in den entsprechenden von dem Jochstück 22 und dem Jochstück 23 einzutreten. Auch betritt der Magnetfluss, der aus den entsprechenden von dem Jochstück 22 und dem Jochstück 23 austritt, angemessen den Magnet 4. Beispielsweise, wird der Weg bzw. Pfad P11 des Magnetflusses, dargestellt in 6, ausgebildet. Der Magnetfluss, der durch den Magnet 3 und den Magnet 4 ausgebildet wird, wird konzentriert, um durch das Magnetelement 15 in der Verlängerungsrichtung zu fließen bzw. zu laufen.
• (6) Die Basis 24 des Jochstückes 22 ist von der Basis 25 des Jochstückes 23 separiert. Zusätzlich befindet sich die Endfläche 24A der Basis 24 parallel zu der Endfläche 25A der Basis 25. Dies erlaubt eine Ausbildung des beispielsweisen Weg bzw. Pfades 11 des Magnetflusses dargestellt in 7. Folglich wird die Richtung des Magnetflusses, die aus einem der Jochstücke 22, 23 austritt und in das andere von den Jochstücken 22, 23 eintritt, gesteuert, derart, dass der Magnetfluss durch das Magnetelement 15 in die Verlängerungsrichtung fließt bzw. läuft.
• (7) Die Basis 24, 25 sind in Übereinstimmung mit dem äußersten Umfang der Spule 16, welche um das Magnetelement 15 gewickelt ist, gebogen. Dies erhöht den Bereich der Abschnitte der Basis 24, 25, die sich benachbart zu dem Magnetelement 15 befinden. Dementsprechend wird die Dichte des Magnetflusses, der aus einem der Jochstücke 22, 23 austritt und durch das Magnetelement 15 in die Verlängerungsrichtung fließt, und in das andere von den Jochstücken 22, 23 eintritt, erhöht.
• (8) Die Jochstücke 22, 23 beinhalten die Seitenwände 26, 27. Die Enden der Seitenwände 26, 27 befinden sich benachbart bzw. nächstliegend bzw. proximal zu dem Magnetelement 15. Dies erlaubt eine Ausbildung beispielsweise des Weges bzw. Pfades P12 des Magnetflusses und des Weges bzw. Pfades P13 des Magnetflusses dargestellt in 6. Folglich tritt der Magnetfluss, welcher durch den Magnet 3 und den Magnet 4 ausgebildet wird, in das Magnetelement 15 von einem Ende des Magnetelements 15 ein und tritt aus dem Magnetelement 15 von dem entgegengesetzten Ende des Magnetelements 15 aus.

The front hub 80 has the advantages described below.

• (1) The structure for detecting the rotational state can be reduced in comparison with the prior art in which a dynamo detects the rotational state.
• (2) The yoke 21 induces the magnetic flux of the magnetic field generated by the magnet 3 and the magnet 4 in the directions orthogonal to the axis of rotation X of the rotating body 82 are magnetized and have different magnetization directions, is formed to pass through the magnetic element 15 to flow in the extension direction. Consequently, even if the distance between the magnet 3 and the magnet 4 is small in the circumferential direction, a magnetic flux between the magnet 3 and the magnet 4 concentrated to pass through the magnetic element 15 to flow in the extension direction. This suitably reverses the magnetization direction of the magnetic element 15 around. More specific are the magnets 3 and the magnets 4 magnetized in one direction, which is the axis of rotation X of the rotating body 82 cuts. Consequently, adjacent to the magnets 3 and the magnet 4 in the circumferential direction of the rotary body 82 , is the area of the magnet 3 having a north pole to the surface of the magnet 4 having a south pole not opposite. This reduces the density of the magnetic flux passing through the shortest path, which linearly equals the north pole of the magnet 3 and the south pole of the magnet 4 which are circumferentially adjacent to each other, even if the distance between the magnet connects 3 and the magnet 4 is small in the circumferential direction. This allows the driving speed of the bike 60 can be accurately detected, due to the rotational speed of the rotating body 82 ,
• (3) The yoke 21 induces the magnetic flux passing through the magnet 3 and the magnet 4 is formed to pass through the magnetic element 15 to flow in the extension direction. Consequently, even if the magnet 3 and the magnet 4 are formed to move in a direction that the axis of rotation X of the rotating body 82 cuts, magnetizes / becomes, the magnetic flux, which by the magnet 3 and the magnet 4 is formed, concentrated to pass through the magnetic element 15 to flow in the extension direction. This increases the density of the magnetic flux passing through the magnetic element 15 running in the extension direction. Accordingly, even if the distance between the magnet 3 and the magnet 4 in the circumferential direction is small, the magnetization direction of the magnetic element becomes 15 in accordance with the magnetic field, which by the magnet 3 and the magnet 4 is formed, vice versa. This allows a reduction of the rotation detector 1 and an improvement in the resolution of the rotation detection.
• (4) The yoke 21 is designed to induce the magnetic flux coming out of the magnet 3 exit and into the magnet 4 enters to pass through the magnetic element 15 to flow in the extension direction. Consequently, the structure of the yoke becomes 21 simplified. This increases the density of magnetic flux passing through the magnetic element 15 in the extension direction, the magnetization direction of the magnetic element runs and reverses 15 in a safe way. More specific, because the magnet 3 and the magnet 4 opposite directions of magnetization in the circumferential direction of the rotating body 82 are the area of the magnet 3 having a north pole and the surface of the magnet 4 having a south pole to the interior of the rotary path L opposite. In addition, there is the magnetic element 15 within the turning path L. This shortens the path of the magnetic flux coming out of the surface of the magnet 3 having a north pole exiting through the magnetic element 15 flows in the extension direction and into the surface of the magnet 4 having a south pole enters and simplifies the shape of the path or path. Consequently, the structure of the yoke becomes 21 , which induces magnetic flux in such a simplified and short path. In addition, the magnetic flux is easily concentrated on the easy and short path. This increases the density of the magnetic flux flowing through the path.
• (5) The yoke pieces 22 . 23 include the projections 28 . 29 , The projection ends of the projections 28 . 29 are adjacent to or closest to the magnet 3 or the magnet 4 passing through the magnetic field application position C or the magnetic field application position D. This shortens the distance between each one of the magnet 3 and the magnet 4 and each of the projections 28 . 29 , This allows the magnetic flux from the magnet 3 exit and appropriate in the appropriate of the Jochstück 22 and the yoke piece 23 enter. Also enters the magnetic flux coming from the corresponding of the yoke piece 22 and the yoke piece 23 exit, appropriate the magnet 4 , For example, the path P11 of the magnetic flux shown in FIG 6 , educated. The magnetic flux passing through the magnet 3 and the magnet 4 is formed, is concentrated to pass through the magnetic element 15 to flow in the extension direction.
• (6) The base 24 of the yoke piece 22 is from the base 25 of the yoke piece 23 separated. In addition, there is the end surface 24A the base 24 parallel to the end face 25A the base 25 , This allows a formation of the exemplary path or path 11 of the magnetic flux shown in 7 , Consequently, the direction of magnetic flux coming from one of the yoke pieces 22 . 23 exit and into the other of the Joch pieces 22 . 23 enters, controlled, such that the magnetic flux through the magnetic element 15 flows in the extension direction or runs.
• (7) The base 24 . 25 are in accordance with the outermost circumference of the coil 16 which are around the magnetic element 15 is wrapped, bent. This increases the range of sections of the base 24 . 25 which is adjacent to the magnetic element 15 are located. Accordingly, the density of the magnetic flux coming from one of the yoke pieces 22 . 23 exit and through the magnetic element 15 flows in the extension direction, and in the other of the Jochstücken 22 . 23 enters, increases.
• (8) The yoke pieces 22 . 23 include the side walls 26 . 27 , The ends of the side walls 26 . 27 are adjacent or proximate to or proximal to the magnetic element 15 , This allows training, for example, the path or path P12 of the magnetic flux and the path or path P13 of the magnetic flux shown in FIG 6 , Consequently, the magnetic flux passing through the magnet 3 and the magnet 4 is formed in the magnetic element 15 from one end of the magnetic element 15 and exits the magnetic element 15 from the opposite end of the magnetic element 15 out.

This further increases the concentration of the magnetic flux passing through the magnetic element 15 flows in the extension direction.

The first embodiment is an example in which the magnetic flux passing through the magnet 3 and the magnet 4 is formed adjacent to each other in the circumferential direction of the rotary body 82 located, to the magnetic element 15 through the yoke 21 is induced. However, the subject matter of the present disclosure is not limited to such a configuration. As in 9 For example, a magnetic flux generated by a magnet can be represented 3 and a magnet 4 which are adjacent to each other in the circumferential direction of the rotary body 82 are formed, to the magnetic element 15 through a yoke 31 , the two yoke pieces 32 . 33 includes, be induced.

 Second embodiment

The 10 and 11 make a rotation detector 41 which is in the front hub 80 is included, which serves as a second embodiment of a bicycle hub. The 10 and 11 show schematically the structure of the rotary detector 41 The second embodiment includes a detecting element which includes magnets 42 , Magnets 43 , the magnetic element 15 and the coil 16 and a yoke 45 , which two yoke pieces 46 . 47 includes.

The rotation detector 41 has the same structure as the rotation detector 1 of the first embodiment except for the following features. At the rotation detector 41 become the magnets 42 and the magnets 43 , which are connected to the rotating body 82 (with reference to 2 ) are fixed, respectively in a direction perpendicular to the rotational axis X of the rotary body 82 magnetized and are in the circumferential direction of the rotating body 82 arranged such that the magnetization directions are alternately opposite to each other. More specifically, every magnet includes 42 a circumferential inner surface having a north pole and a peripheral outer surface having a south pole. Every magnet 43 includes a circumferential inner surface having a south pole and a peripheral outer surface having a north pole. The magnets 42 . 43 are located towards one end of the magnetic element 15 in the extension direction. The rotary path of the magnets 42 and the magnets 43 includes a magnetic field application position which is a position indicated by a single-dashed line F in FIG 11 is marked. The 10 represents one of the magnets 42 and the magnet 43 which is in the rotary body 82 located at the magnetic field application position.

The yoke 45 includes the two yoke pieces 46 . 47 , The yoke piece 46 is located at a position corresponding to one end of the magnetic element 15 , The yoke piece 47 is located at a position corresponding to the other end of the magnetic element 15 , If one of the magnets 42 and the magnet 43 is located at the magnetic field application position, the magnet is only adjacent to the yoke piece 46 ,

As in 11 shown when the magnet 42 reaches the magnetic field applying position, a magnetic flux passing through the magnet 42 is formed through the yoke 45 induced. This forms a path P21 of the magnetic flux coming out of the surface of the magnet 42 having a north pole exiting through the magnetic element 15 flows in the extension direction, and in the surface of the magnet 42 having a south pole occurs. If one of the magnets 43 reaches the magnetic field applying position, the direction of the magnetic flux in the path P21 is opposite to the direction shown in FIG 10 ,

The front hub 80 that the turn detector 41 also concentrates a magnetic flux formed by a magnet passing through the magnetic field applying position such that the magnetic flux passes through the magnetic element 15 flows in the extension direction. Consequently, even if the distance between magnets in the circumferential direction is small, the magnetic field formed by the magnets properly returns the magnetization direction of the magnetic element 15 around. This allows a reduction of the rotation detector 41 and an improvement in the resolution of the rotation detection.

 Third embodiment

12 and 13 make a rotation detector 51 which is in the front hub 80 is included, which serves as a third embodiment of a bicycle hub. The 12 and 13 show schematically the structure of the rotary detector 51 The third embodiment includes a detecting element 14 which includes magnets 52 , Magnets 53 , the magnetic element 15 and the coil 16 , and a yoke 55 , which two yoke pieces 56 . 57 includes.

The rotation detector 51 has the same structure as the rotation detector 1 of the first embodiment except for the following features. At the rotation detector 51 are the magnets 52 and the magnets 53 to the rotary body 82 (with reference to 2 ) fixed. Every magnet 52 includes a magnet piece 52A and a magnet piece 52B which serve as magnetic field forming pieces. The magnet piece 52A and the magnet piece 52B are each in a direction perpendicular to the rotational axis X of the rotating body 82 magnetized.

With every magnet 52 are the magnet piece 52A and the magnet piece 52B in a direction parallel to the rotation axis X of the rotary body 82 arranged such that the magnetization directions are opposite to each other.

In the same way as the magnets 52 , includes every magnet 53 a magnet piece 53A and a magnet piece 53B , The magnets 52 and the magnets 53 are in a circumferential direction of the rotating body 82 arranged such that the magnetization directions of the magnet pieces 52A and the magnet pieces 53A alternately to each other in the circumferential direction of the rotating body 82 are opposite, and such that the magnetization directions of the magnet pieces 52B and the magnet pieces 53B alternately to each other in the circumferential direction of the rotating body 82 are opposite. More specifically, each of the magnet pieces includes 52A and the magnet pieces 53B a circumferential inner surface having a north pole and a peripheral outer surface having a south pole. Everyone from the magnet pieces 53A and the magnet pieces 52B includes a circumferential inner surface having a south pole and a peripheral outer surface having a north pole. The rotary path of the magnets 52 and the magnets 53 include a magnetic field application position which is a position indicated by a single-dashed line G shown in FIG 12 , is marked. 12 shows the magnet 52 , one of the magnets 52 and the magnet 53 which is in the rotating body 82 and is located at the magnetic field application position.

The yoke 55 includes two yoke pieces 56 . 57 , The yoke piece 56 is located at a position corresponding to one end of the magnetic element 15 , The yoke piece 57 is located at a position corresponding to the other end of the magnetic element 15 , If one of the magnet 52 and the magnet 53 is located at the magnetic field application position, is the corresponding of the magnet pieces 52A and magnet pieces 53A adjacent to the yoke piece 56 and the corresponding one of the magnet pieces 52B and magnet pieces 53B is located adjacent to the yoke piece 57 ,

At the rotation detector 51 having the above structure as in 12 shown when one of the magnets 52 reaches the magnetic field applying position, a magnetic flux passing through the magnet piece 52A and the magnet piece 52B of the magnet 52 is formed through the yoke 55 induced. This forms a path P31 of the magnetic flux coming out of the magnet piece 52A of the magnet 52 exit, through the magnetic element 15 in the extension direction flows and the magnet piece 52B of the magnet 52 entry. If one of the magnets 53 reaches the magnetic field applying position, a magnetic flux passing through the magnet piece 53A and the magnet piece 53B of the magnet 53 is formed through the yoke 55 induced. This forms a path of the magnetic flux coming out of the magnet piece 53A of the magnet 53 exit, through the magnetic element 15 flowing in the extension direction and into the magnet piece 53B of the magnet 53 entry.

The rotation detector 51 having the above structure also concentrates a magnetic flux formed by a magnet flowing through the magnetic field such that the magnetic flux passes through the magnetic element 15 flows in the extension direction. Consequently, even if the distance between the magnets in the circumferential direction is short, the magnetic field formed by the magnets properly returns the magnetization direction of the magnetic element 15 around. This allows a reduction of the rotation detector 51 and an improvement in the resolution of the rotation detection.

 Fourth embodiment

14 shows a cross section of a front hub 90 , which serves as a fourth embodiment of a bicycle hub. The front hub 90 has the same structure as the front hub 80 of the first embodiment, except for the shape of a shaft 91 and the position of the rotation detector 1 ,

As in 14 represented is the wave 91 a hollow hub shaft attached to the frame 61 (with reference to 1 ) of the bicycle 60 can be coupled. The wave 91 includes a hole 91A leading to an inner surface of the rotating body 82 is open.

The supporting body 11 is through an inner surface of the shaft 91 supported. The supporting body 11 may have a size that allows the support body 11 through the inner surface of the shaft 91 can be supported. Alternatively, the support body 11 on the inner surface of the shaft 91 through the fixation member 6 be supported. The yoke 21 of the rotary detector 1 is inside the shaft 91 and is one of the magnets 3 and the magnets 4 through the hole 91A opposed. The projections 28 . 29 of the yoke 21 are in the wave 91 , The hole 91A can be at a position corresponding to each of the tabs 28 . 29 are located.

• (9) Der Drehdetektor 1 befindet sich innerhalb der Hohlwelle 91. Dies erlaubt eine Verkleinerung der vorderen Nabe 90.

The front hub 90 has the advantage as described below, in addition to the advantages (1) to (8).

• (9) The rotation detector 1 located inside the hollow shaft 91 , This allows a reduction of the front hub 90 ,

Fifth embodiment

15 shows the rear hub 66 , which serves as a fifth embodiment of a bicycle hub. The rear hub 66 includes a wave 103 , a rotating body 100 and the rotation detector 1 , The rear hub 66 preferably includes a hub shell 101 , two coupling links 102 , a first roller bearing 104. , a second roller bearing 105 , a third roller bearing 107 and a fourth roller bearing 108 , The wave 103 is a hub shaft.

The rotary body 100 is a freewheel that rotates in one direction only to the hub shell 101 transmits and is located adjacent to the hub shell in the axial direction. The rotary body 100 is about the axis 103 rotatable. The rear sprocket 71 is at the periphery of the rotating body 100 coupled in a removable way. The rotary body 100 includes a tubular member 106 and a one-way clutch 110 , The rear sprocket 71 can be attached to the circumference of the tubular body 106 be coupled. The one-way clutch 110 only transmits a forward direction of the tubular member 106 to the hub shell 101 , The tubular member 106 is about the wave 103 relative to the hub shell 101 rotatable in one direction and with the hub shell 101 integral in the opposite direction. The one-way clutch 110 couples one end of the tubular member 106 and one end of the hub shell 101 that is mutually in the axial direction of the shaft 103 are opposite.

The hub shell 101 is about the wave 103 rotatable.

The two coupling links 102 are at opposite ends of the shaft 103 coupled. The coupling links 102 are designed to attach to the frame 61 (referring to the 1 ) be coupled. The wave 103 and the coupling members 102 are hollow. The wave 103 gets to the frame 61 through a mooring mechanism 109 attached in a removable way. The mooring mechanism 109 includes a shaft 109A which is in the wave 103 and the coupling members 102 located.

The first roller bearing 104. includes an outer ring 104A , which on the hub shell 101 coupled, an inner ring 104B which through the shaft 103 is supported, and rolling elements 104C passing through the outer ring 104A and the inner ring 104B are / are supported. The first roller bearing 104. supports one end of the hub shell 101 with respect to the axial direction of the shaft 103 , The third roller bearing 107 has the same structure as the first roller bearing 104. and supports the other end of the hub shell 101 with respect to the axial direction of the shaft 103 ,

The second roller bearing 105 includes an outer ring 105A , which is integral with the tubular member 106 of the rotary body 100 is formed, an inner ring 105B which through the shaft 103 is / is supported, and rolling elements 105C passing through the outer ring 105A and the inner ring 105B are / are supported. The first roller bearing 105 supports one end of the tubular member 106 with respect to the axial direction of the shaft 103 , The fourth roller bearing 108 has the same structure as the third roller bearing 107 and supports the other end of the tubular member 106 with respect to the axial direction of the shaft 103 ,

The supporting body 11 of the rotary detector 1 is to the wave 103 coupled. The magnets 3 and the magnets 4 of the rotary detector 1 are at the recesses 106A , which are located on the inner surface of the tubular member 106 of the rotary body 100 are coupled. The supporting body 11 , which is a section of the rotary detector 1 is located between the shaft 103 and the rotary body 100 ,

The operation of the rear hub 66 will now be with reference to the 1 and 15 described.

When a human powered force on the pedals 69 is applied to the crank arms 67 to turn forward, turn the front sprocket 70 , the chain 72 and the rear sprocket 71 the rotating body 100 Forward. The rotation of the rotating body 100 turns the magnets 3 and the magnets 4 , which on the tubular member 106 of the rotary body 100 are coupled. The rotational speed of a crank may be due to a rotational speed of the rotary body 100 passing through the rotary detector 1 the rear hub 66 is detected, are calculated. The rotational speed of the crank may be due to the gear ratio and the rotational speed of the rotating body 100 be calculated. The rear hub 66 has the same advantages as the advantages (1) to (8).

Modified examples

The foregoing description is intended to be illustrative only and not restrictive. The subject matter of the present disclosure is not limited to the above embodiments, and may be modified as follows. Two or more modified examples may be appropriately combined.

In a modified example the first not bike includes the front hub 80 a wave, which is in the rotating body 82 in addition to the wave 81 and a rotary member which is synchronous with the rotary body with respect to the shaft 82 rotates. In this modified example, the rotation detector detects 1 the front hub 80 a rotation of the rotary member.

Not a modified example of the fourth embodiment is the rotation detector 1 the front hub 90 at least partially from the hole 91A the wave 91 exposed and to the magnets 3 and the magnet 4 opposed.

In a modified example of the embodiment, the rear hub includes 66 the hollow shaft 103 including a hole. The rear hub 66 This modified example includes the rotation detector 1 who is in the wave 103 is located to the magnets 3 and the magnet 4 through the hole is opposite. Alternatively, at least a portion of the rotation detector 1 exposed and to the magnets 3 and the magnet 4 opposed.

The bicycle hub of each embodiment may include a calculation processor unit, such as a microcomputer, which estimates the bicycle speed or cadence of the crank based on the detection result of the rotation detector 1 calculated.

At the front hub 80 In the first embodiment, the magnets 3 . 4 to the inner surface of the rotary body 82 without the formation of the recesses 82A in the rotary body 82 to be fixed. The front hub 80 The fourth embodiment may be configured in the same way.

At the rear hub 66 According to the fifth embodiment, the magnets 3 . 4 to the inner surface of the tubular member 106 without the formation of the recesses 106A in the tubular member 106 to be fixed.

The rotation detector 1 may be included in a rear hub that includes a gearshift device that includes gears and gear ratios and is located in the hub shell. In such a rear hub is the rotation detector 1 in the hub shell, the detection unit 7 is located in a shaft and from the hub shaft, and the magnets are in a rotary member that rotates with respect to the shaft, different from the hub shaft, in synchronism with at least one of the hub shell and the rear sprocket.

DESCRIPTION OF THE REFERENCE SIGNS

• 1 . 41 . 51 · Rotation detector; 3 . 4 . 42 . 43 . 52 . 53 · Magnet (magnetic field forming section); 14 · Detecting element; 15 · Magnetic element; 21 . 31 . 45 . 55 · Yoke (magnetic flux induction body); 52A . 52B . 53A . 53B · Magnetic piece (magnetic field forming piece); 60 ·Bicycle; 61 ·Frame; 66 · Rear hub (bicycle hub); 80 . 90 · Front hub (bicycle hub); 81 . 91 . 103 ·Wave; 82 . 100 · Rotating body; 91A ·Hole; 101 · Hub shell

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 7-229909 [0002]
• JP 2001-194182 [0040]

Claims (17)

 Bicycle hub, comprising: a wave; a rotary body which is rotatable with respect to the shaft; and a rotation detector detecting rotation of the rotary body, the rotation detector including magnetic field forming portions located on the rotary body, the magnetic field forming portions each of which is magnetized in a direction intersecting a rotation axis of the rotary body are arranged in a circumferential direction of the rotary body such that the magnetization directions are alternately opposite to each other; a magnetic member located within a rotational path of the magnetic field forming portions, the magnetic member extending in a direction extending along the rotational axis of the rotary body and having a magnetization direction in the direction extending along the rotational axis of the rotary body is reversed by a magnetic field formed by at least one magnetic field forming portions; a coil wound around the magnetic element; and a magnetic flux induction body located between the rotation path and the magnetic member, wherein when the at least one magnetic field forming portion passes through a predetermined position in the rotation path, the magnetic flux induction body induces a magnetic flux formed through the at least one magnetic field forming portions is / is to pass through the magnetic member in the direction extending along the rotational axis of the rotary body.  A bicycle hub according to claim 1, wherein the shaft is configured to be a hub shaft that may be coupled to a frame of a bicycle; and the rotary body is configured to be a hub shell rotating with respect to the hub shaft.  A bicycle hub according to claim 2, wherein the magnetic field forming portions are coupled to the hub shell.  A bicycle hub according to claim 2 or 3, wherein at least a portion of the rotary detector is located between the hub shaft and the hub shell.  A bicycle hub according to claim 2 or 3, wherein the hub shell includes an inner surface; the hub shaft is hollow and includes a hole opposite or facing the inner surface of the hub shell; and the magnetic flux induction body is located in the hub shaft and is opposed to the magnetic field forming portions through the hole, or at least a portion of the magnetic flux induction body is exposed from the hole and is opposed to the magnetic field forming portions.  A bicycle hub according to claim 1, wherein the shaft is formed to be a hub shaft that may be coupled to a frame of a bicycle; and the rotary body is configured to be a freewheel located adjacent to a hub shell in an axial direction and transmitting rotation in only one direction to the hub shell.  A bicycle hub according to claim 6, wherein the magnetic field forming portions are coupled to the freewheel.  A bicycle hub according to claim 6 or 7, wherein at least a portion of the rotation detector is between the hub shaft and the freewheel.  A bicycle hub according to claim 6 or 7, wherein the freewheel includes an inner surface; the hub shaft is hollow and includes a hole, opposite or facing the inner surface of the freewheel; and the magnetic flux induction body is located in the hub shaft and is opposed to the magnetic field forming portions through the hole, or at least a portion of the magnetic flux induction body is exposed from the hole and is opposed to the magnetic field forming portions.  A bicycle hub according to any one of claims 1 to 9, wherein when one of two magnetic field forming portions of which the magnetization directions are opposite to each other passes through a first predetermined position in the turning path and the other of the two magnetic field forming portions passes through at the same time a second predetermined position in the rotation path, the magnetic flux induction body induces a magnetic flux exiting from one of the magnetic field forming portions and entering the other magnetic field forming portions such that the magnetic flux passes through the magnetic member in the direction along the axis of rotation of the rotary body extends, runs. A bicycle hub according to claim 10, wherein the magnetic flux induction body includes two yoke pieces; wherein the two yoke pieces are separated from each other and opposed to each other in the direction extending along the rotational axis of the rotary body; each of the two yoke pieces includes a protrusion projecting toward the turning path; and when one of two magnetic field forming portions having the magnetization directions opposite to each other is in the vicinity of the projection of one of the two yoke pieces, the other one of the two magnetic field forming portions is located near the projection from the other of the two yoke pieces.  A bicycle hub according to claim 11, wherein one of the two yoke pieces is in a position corresponding to one end of the magnetic member; and the other of the two yoke pieces is at a position corresponding to the other end of the magnetic member.  A bicycle hub according to claim 12, wherein each of the two yoke pieces is formed by a plate-shaped member; and the member bends according to an outermost circumference of the coil wound around the magnetic member.  A bicycle hub according to claim 12, wherein each of the two yoke pieces is formed by a plate-shaped member; and the member extends from a position corresponding to a portion of the magnetic member around which the coil is wound to a position corresponding to a portion of the magnetic member which is free from the coil, and then bends and extends to be adjacent to To be magnetic element.  A bicycle hub according to any one of claims 1 to 14, wherein when one of the magnetic field forming portions passes through a predetermined position in the rotary path, the magnetic flux induction body induces magnetic flux exiting from one surface of the magnetic field forming portion and forming another surface of the magnetic field Enters portion with respect to a radial direction of the rotary body, such that the magnetic flux passes through the magnetic element in the direction extending along the rotational axis of the rotary body.  A bicycle hub according to any one of claims 1 to 15, wherein each of the magnetic field forming portions includes a first magnetic field forming piece and a second magnetic field forming piece, each of which is magnetized in a direction intersecting the rotational axis of the rotary body; the first magnetic field forming piece and the second magnetic field forming piece are arranged in the direction extending along the rotation axis of the rotary body, such that the magnetization directions are opposite to each other; the magnetic field forming portions are arranged in the circumferential direction of the rotary body such that the magnetization directions of the first magnetic field forming piece are alternately opposite to each other in the circumferential direction of the rotary body and such that the magnetization directions of the second magnetic field forming piece are alternately opposite to each other in the circumferential direction of the rotary body are; and When one of the magnetic field forming portions passes through a predetermined position in the rotation path, the magnetic flux induction body induces a magnetic flux exiting from one of the first magnetic field forming piece and the second magnetic field forming portion of magnetic field forming portions and the other forming the first magnetic field Piece and second magnetic field forming portion of the magnetic field forming portions enters, such that the magnetic flux passes through the magnetic element in the direction that extends along the axis of rotation of the rotary body runs.  A bicycle hub according to any one of claims 1 to 16, wherein the magnetic element is a large Barkhausen element.

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