DE202016107379U1 - Reinforcing cylinder for a hub - Google Patents

Abstract

A reinforcing cylinder for a hub (200), comprising: a hollow body (1) comprising: a surrounding wall (11) surrounding an axis (L) and having an inner and an outer surrounding surface (112, 111 ) facing each other, a plurality of transmission portions (12) formed on the outer peripheral surface (111) and spaced at an angle about the axis (L), and at least one positioning portion (13) located on the outer peripheral surface (111) is formed and which is formed between two adjacent ones of the transmission portions (12), and at least one reinforcing member (2) which is arranged on the at least one positioning portion (13) and is made of a material having a mechanical strength higher than that of the hollow body (1), characterized in that: the at least one positioning portion (13) has a flat contact surface (131) and a passage opening (14) extending from the contact surface (131) to the inner surrounding surface (112); and the at least one reinforcing member (2) has a main portion (21) having a connecting surface (211) that is flat and attached to the contact surface (131) of the at least one positioning portion (13), and a positioning protrusion (22) is connected to the main portion (21) and which is press-fitted into the passage opening (14).

Description

The disclosure relates to a bicycle component, and more particularly to a hub for a hub.

A conventional reinforcing cylinder for a hub of a bicycle, such as the one in the Taiwanese Patent No. I393641 disclosed, it is designed for secure attachment of a plurality of flywheels. The conventional reinforcing cylinder comprises a hollow body and three reinforcing members. The hollow body has a surrounding wall surrounding an axis and having an outer surrounding surface, a plurality of transmission portions formed on the outer surrounding surface and spaced at an angle about the axis, three positioning portions respectively between two adjacent ones Transmission portions are formed and each having a curved contact surface, three grooves, which are each formed in the contact surfaces, and three stop members, which are respectively arranged on the contact surfaces and each aligned with the grooves in an axial direction, on. The reinforcing members are respectively fixed to the positioning portions of the hollow body and have a structural strength higher than that of the transmitting portions of the hollow body. Each of the reinforcing members includes a main portion corresponding in position to a respective one of the positioning portions, and a positioning protrusion projecting from the main portion and press-fitted into a respective one of the grooves. The main portion of each of the reinforcement members has a curved connection surface attached to the contact surface of the respective one of the positioning portions.

The flywheels are secured to the transfer portions of the hollow body and the reinforcing members, so that when the flywheels are driven for rotation by a chain of the bicycle, contact zones between the flywheels and the conventional reinforcing cylinder transfer the force generated by the rotation of the flywheels from the Allow flywheels on the hub to turn a rear wheel of the bicycle. The reinforcing members bear the force applied thereto and prevent deformation of the transmitting portions of the hollow body. However, since the contact surfaces of the positioning portions of the hollow body and the connecting surfaces of the reinforcing members are curved surfaces, a relatively high manufacturing precision is required, which is not easily achieved. Moreover, each of the connecting surfaces may not touch the respective one of the contact surfaces inconsistently due to dimensional tolerance, thereby not only impairing the quality of mounting of the conventional reinforcing cylinder, but also causing transmission of uneven force from the connecting surfaces to the respective contact surfaces upon rotation of the flywheels , Moreover, since the grooves do not extend through the surrounding wall, the coupling strength between the reinforcing members and the hollow body, which is positively correlated with a depth of the grooves, may not be sufficient for stably securing the reinforcing members to the hollow body.

Thus, an object of the disclosure is to provide a reinforcing cylinder that mitigates at least one of the disadvantages of the prior art.

According to the disclosure, the reinforcing cylinder for a hub comprises a hollow body and at least one reinforcing member. The hollow body has a surrounding wall, a plurality of transmission sections and at least one positioning section. The surrounding wall surrounds an axis and has an inner and an outer surrounding surface which face each other. The transfer sections are formed on the outer surrounding surface and spaced at an angle about the axis. The at least one positioning portion is formed on the outer surrounding surface, is disposed between two adjacent ones of the transmitting portions, and has a flat contact surface. The at least one reinforcing member is disposed on the at least one positioning portion and is made of a material having a mechanical strength higher than that of the hollow body. The hollow body further includes a passage opening extending from the contact surface to the inner surrounding surface. The at least one reinforcing member has a main portion having a connecting surface that is flat and attached to the contact surface of the at least one positioning portion, and a positioning protrusion connected to the main portion and press-fitted into the through-hole.

Other features and advantages of the disclosure will be apparent from the following detailed description of the embodiment with reference to the accompanying drawings, in which:

1 FIG. 4 is an exploded perspective view illustrating one embodiment of a reinforcing cylinder according to the disclosure; FIG.

2 Fig. 12 is a schematic sectional view illustrating a plurality of flywheels attached to the embodiment;

3 Fig. 10 is a fragmentary enlarged exploded sectional view of the embodiment;

4 Fig. 10 is a sectional view illustrating an arrangement of a hub comprising the reinforcing cylinder of the embodiment; and

5 a partially cutaway perspective view illustrating two holding webs of the embodiment.

Regarding 1 to 4 is an embodiment of a reinforcing cylinder for a hub 200 according to the disclosure for secure attachment of multiple flywheels 100 a bicycle (not shown) made thereon. The reinforcing cylinder comprises a hollow body 1 , three reinforcing links 2 and two retaining bars 3 ,

In this embodiment, the hollow body is 1 tubular and has a surrounding wall 11 , six transmission sections 12 , three positioning sections 13 , three passages 14 and nine grooves 15 on. The surrounding wall 11 surrounds an axis (L) and has an inner and an outer surrounding surface 112 . 111 that are facing each other up. The transmission sections 12 are on the outer surrounding surface 111 formed and spaced at an angle about the axis (L). The positioning sections 13 are on the outer surrounding surface 111 educated. Each of the positioning sections 13 is between two adjacent ones of the transmission sections 12 arranged and has a flat contact surface 131 on. The transmission sections 12 and the positioning sections 13 extend parallel to the axis (L). Each of the passages 14 extends from the contact surface 131 a respective one of the positioning sections 13 to the inner surrounding area 112 , Each of the grooves 15 is in the outer surrounding area 111 formed extends to the axis (L) and ends in a groove bottom end 151 ,

The transmission sections 12 are arranged in pairs, each of the positioning sections 13 between two adjacent pairs of the transmission sections 12 is arranged and positioned. Each of the grooves 15 is between two adjacent ones of the positioning sections 13 and the transmission sections 12 educated. That means each of the grooves 15 either between two adjacent ones of the transmission sections 12 or between one of the positioning sections 13 and an adjacent one of the transmission sections 12 is trained. In this embodiment, the positioning portions 13 with respect to the axis (L) equiangularly spaced apart. In a variation of the embodiment, the positioning portions 13 arranged at an angle, but unevenly spaced from each other. In one example, the positioning sections 13 adjacent to each other and through corresponding ones of the grooves 15 be spaced apart.

The reinforcing members 2 are each at the positioning sections 13 arranged and made of a material having a mechanical strength, which is above that of the hollow body 1 lies. Each of the reinforcing members 2 has a main section 21 on top of that, a connecting surface 211 that is flat and at the contact surface 131 a respective one of the positioning sections 13 attached, and a distal surface 212 that of the interface 211 with respect to the axis (L) opposite, having. Each of the reinforcing members 2 also has a positioning projection 22 on that with the main section 21 connected to the distal surface 212 projecting toward the axis (L) and into a respective one of the passage openings 14 is press-fitted.

It is worth noting that in this embodiment, each of the positioning portions 13 is configured as a protruding platform, leaving a distance between the contact surface 131 each of the positioning sections 13 and the axis (L) greater than that between the groove bottom end 151 each of the grooves 15 and the axis (L) is as in 3 will be shown. In a variation of the embodiment, the reinforcing cylinder may function properly as long as a distance between the distal surface 212 each of the reinforcing members 2 and the axis (L) greater than that between the groove bottom end 151 each of the grooves 15 and the axis (L) is, which means that the distance between the contact surface 131 each of the positioning sections 13 and the axis (L) smaller than that between the groove bottom end 151 each of the grooves 15 and the axis (L) can be.

Regarding 5 surround the retaining bars 3 the axis (L), are on the inner surrounding surface 112 formed and spaced along the axis (L). The retaining bars 3 divide the inner surrounding area 112 together in a first area 31 , a second area 32 and a third area 33 , The second area 32 is between the retaining bars 3 positioned and through it extend the passage openings 14 , The retaining bars 3 are to the respective plant of two camps 300 (please refer 4 ), so that the bearings 300 in the first and the third area, respectively 31 . 33 being held.

It is also worth noting that each of the passages 14 a depth (D) (see 3 ) from the contact surface 131 the respective one of the positioning sections 13 to the inner surrounding area 112 having the following formula: 1.5mm ≦ D ≦ 3, 0mm.

In this embodiment, the positioning projection 22 each of the reinforcing members 2 one from the main section 21 distal end that extends through the respective one of the passage openings 14 extends through and from the inner surrounding surface 112 the surrounding wall 11 protrudes, as in 5 will be shown. Alternatively, the end of the positioning projection 22 each of the reinforcing members 2 with the inner surrounding area 112 be flush. With an increase in the depth (D) of the openings 14 becomes the coupling strength between the positioning protrusions 22 and the respective passage openings 14 effectively improved compared to that of the conventional reinforcing cylinder, and the reinforcing members 2 stand in safer engagement with the hollow body 1 ,

Referring again to 1 . 2 and 4 are the flywheels 100 of the bicycle to the reinforcing members 2 and the transmission sections 12 of the hollow body 1 secured and driven by a chain (not shown) of the bicycle for rotation about the axis (L), thereby rotation of the hub 200 drive. During rotation, the reinforcing members can 2 the flywheels 100 applied thereto force and prevent deformation of the transmission sections 12 of the hollow body 1 , Because the connecting surfaces 211 the reinforcing members 2 and the contact surfaces 131 of the positioning section 13 of the hollow body 1 flat surfaces and by engagement of the positioning projections 22 and the respective passage openings 14 secured in close contact, the power of the flywheels can 100 evenly on the connecting surfaces 211 and the respective contact surfaces 131 be transmitted, whereby a uniform distribution and transmission of the force is ensured and a deformation of the reinforcing members 2 and the transmission sections 12 of the hollow body 1 is prevented.

In short, the contact surfaces 131 and the connection surfaces 211 the revelation is configured flat in comparison to the above-mentioned conventional reinforcing cylinder, whereby the force from the flywheels 100 can be evenly distributed on the reinforcing cylinder to prevent deformation, and the manufacturing cost of the reinforcing cylinder are relatively low, since manufacturing precision for flat surfaces can be more easily achieved than for curved surfaces. In addition, the coupling strength between the reinforcing members 12 and the hollow body 1 , as the passage openings 14 completely through the inner surrounding area 112 the surrounding wall 11 of the hollow body 1 extend, effectively increasing, so that the reinforcing members 2 safer with the hollow body 1 engage.

In the above description, for purposes of explanation, numerous specific details have been set forth in order to provide a thorough understanding of the embodiment. However, it will be apparent to those skilled in the art that one or more other embodiments may be practiced without some of these specific details. It is further understood that throughout the specification, references to "one embodiment", an embodiment including an ordinal number, etc., mean that a particular feature, structure, or characteristic may be included in the implementation of the disclosure. It is also to be understood that for purposes of facilitating disclosure and understanding of the various inventive aspects throughout the specification, various features may be combined in a single embodiment, figure, or description thereof.

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

• TW 393641 [0002]

Claims (7)

Reinforcing cylinder for a hub ( 200 ), comprising: a hollow body ( 1 ) comprising: a surrounding wall ( 11 ) which surrounds an axis (L) and which has an inner and an outer surrounding surface ( 112 . 111 ), which are opposite each other, has several transmission sections ( 12 ) on the outer surrounding surface ( 111 ) and which are spaced at an angle about the axis (L) and at least one positioning portion (14) 13 ) located on the outer surrounding surface ( 111 ) and between two adjacent of the transmission sections ( 12 ) is formed, and at least one reinforcing member ( 2 ) located at the at least one positioning section ( 13 ) and is made of a material having a mechanical strength which exceeds that of the hollow body ( 1 ), characterized in that: the at least one positioning section ( 13 ) a flat contact surface ( 131 ) and a passage opening ( 14 ) extending from the contact surface ( 131 ) extends to the inner surrounding surface ( 112 ), having; and the at least one reinforcing member ( 2 ) a main section ( 21 ), which has a connection surface ( 211 ), which is flat and at the contact surface ( 131 ) of the at least one positioning section ( 13 ) and a positioning projection ( 22 ), with the main section ( 21 ) and in the passage opening ( 14 ) is press-fitted. Reinforcement cylinder according to claim 1, further characterized in that the hollow body ( 1 ) further a plurality of grooves ( 15 ), each in the outer surrounding surface ( 111 ) and between two adjacent ones of the at least one positioning section ( 13 ) and the transmission sections ( 12 ) is formed, wherein each of the grooves ( 15 ) extends to the axis (L) and at a groove bottom end ( 151 ) ends; the main section ( 21 ) of the at least one reinforcing member ( 2 ) a distal surface ( 212 ), which the connection surface ( 211 ) is opposite to the axis (L); and a distance between the distal surface ( 212 ) and the axis (L) greater than that between the groove bottom end ( 151 ) each of the grooves ( 15 ) and the axis (L) is. Reinforcing cylinder according to claim 2, further characterized in that a distance between the contact surface ( 131 ) of the at least one positioning section ( 13 ) and the axis (L) greater than that between the groove bottom end ( 151 ) each of the grooves ( 15 ) and the axis (L) is. Reinforcement cylinder according to one of claims 2 and 3, further characterized in that the passage opening ( 14 ) a depth (D) of the contact surface ( 131 ) to the inner surrounding surface ( 112 ), satisfying a following formula: 1.5mm ≦ D ≦ 3, 0mm. Reinforcing cylinder according to claim 4, further characterized in that the positioning projection ( 22 ) of the at least one reinforcing member ( 2 ) one of the main section ( 21 ) distal end extending through the passage opening ( 14 ) and from the inner surrounding surface ( 112 ) of the surrounding wall ( 11 ) protrudes. Reinforcement cylinder according to one of the preceding claims, characterized by two retaining webs ( 3 ), which surround the axis (L), on the inner surrounding surface ( 112 ) are formed and spaced along the axis (L), wherein the retaining webs ( 3 ) the inner surrounding surface ( 112 ) together into a first area ( 31 ), a second area ( 32 ) and a third area ( 33 ), wherein the second area between the retaining webs ( 3 ) is positioned and through him the passage openings ( 14 ). Reinforcement cylinder according to one of the preceding claims, further characterized in that the transmission sections ( 12 ) and the at least one positioning section ( 13 ) of the hollow body ( 1 ) extend parallel to the axis (L).

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