阅读说明：本技术 用于备用车轮的固定件 (Fixing piece for spare wheel ) 是由 弗朗西斯科·克里亚多德尔皮诺 弗朗西斯科·库尔瓦斯弗洛里多 伊万·西普雷斯巴勒斯特 于 2021-05-31 设计创作，主要内容包括：提供了一种用于将备用车轮紧固到结构、例如车辆的一部分上的固定件,该固定件包括具有凸耳的连接器,该凸耳被配置成使得该固定件相对于该结构的旋转将该凸耳移动到该结构的凹部中,以将该固定件紧固到该结构上；并且其中,该连接器进一步包括弹性铰接臂,该弹性铰接臂被布置成在该固定件连接至该结构时在该固定件与该结构之间起作用以将该凸耳推入该凹部中。(There is provided a fastener for fastening a spare wheel to a structure, for example a part of a vehicle, the fastener comprising a connector having a lug configured such that rotation of the fastener relative to the structure moves the lug into a recess of the structure to fasten the fastener to the structure; and wherein the connector further comprises a resilient hinge arm arranged to act between the mount and the structure to push the lug into the recess when the mount is connected to the structure.)

1. A fastener for fastening a spare wheel to a structure, such as a part of a vehicle, the fastener comprising a connector having a lug arranged such that rotation of the fastener relative to the structure moves the lug into a recess of the structure to fasten the fastener to the structure; and is

Wherein the connector further comprises a resilient hinge arm arranged to act between the mount and the structure to push the lug into the recess when the mount is connected to the structure.

2. The fixture of claim 1, further comprising a shaft, wherein the connector is disposed at one end of the shaft, the shaft including a shoulder, and wherein the resilient hinge arm extends from the shoulder in an axial direction of the shaft.

3. The mount of claim 2, wherein the resilient hinge arm includes a first hinge at a junction between the resilient hinge arm and the shoulder, the first hinge being resiliently bendable.

4. The mount of claim 3, wherein an end of the resilient hinged arm opposite the first hinge is a free end, and wherein the resilient hinged arm further comprises a second hinge disposed between the first hinge and the free end.

5. The mount of claim 4, wherein the second hinge is curved in a direction opposite the first hinge.

6. The fixing as claimed in any preceding claim, wherein the resilient hinge arms are an integrally moulded part of the fixing.

7. A securing system for securing a spare wheel to a vehicle, the securing system comprising:

a structure, such as a portion of a vehicle, the structure including a recess; and

the fixture as claimed in any one of claims 1 to 6, the lug of the fixture being configured to engage the recess of the structure to connect the fixture to the structure.

Technical Field

The present invention relates to a fastener for fastening a spare wheel to a structure, such as a part of a vehicle.

Background

In a vehicle such as an automobile, spare wheels are generally loaded in a trunk (trunk). Fasteners (e.g., bolts) are used to hold the spare wheel in place. The fasteners are typically attached to corresponding fastening features on the vehicle, such as threaded holes formed in a plate on the floor of the vehicle's trunk. In particular, conventional fixtures on the market today generally require weld nuts 1, 2 and metal screws 3, 4 in the automobile body, as shown in fig. 1(a) to 1 (d). Another solution is shown in fig. 2(a) to 2(c), where an additional plastic holder 5 is used to fasten a plastic screw 6. Further, the fixture shown in fig. 3 requires plastic screws 7 releasably coupled to specific metal brackets 8 in order to be in coupled engagement with corresponding counterparts for fastening the wheel.

However, all of these known solutions require multiple components to provide the proper tension between the stationary assembly and the spare wheel.

It is therefore an object of the present invention to provide an improved fastener having fewer parts, minimizing manufacturing costs, and increasing ease of use during installation or removal of the wheel.

Disclosure of Invention

According to the present invention there is provided a fastener for fastening a spare wheel to a structure (e.g. a part of a vehicle), the fastener comprising a connector having a lug configured such that rotation of the fastener relative to the structure moves the lug into a recess of the structure to fasten the fastener to the structure; and wherein the connector further comprises a resilient hinge arm arranged to act between the mount and the structure when the mount is connected to the structure to push the lug into the recess.

The resilient hinge arms act as biasing members between the structure and the mount to retain the lugs in the recesses. During use, the resilient hinge arms provide a biasing force that urges the securing member away from the structure such that the securing member can be connected to the structure by a push-turn action that moves the lugs into the recesses.

During use, for example in a vehicle, the resilient hinge arms may advantageously prevent the lugs from moving out of the recesses due to movement and vibration generated by the vehicle.

In addition, the resilient hinge arms may be integrally molded as part of the fixture, which facilitates manufacturing since a separate biasing member (e.g., a spring or resilient ring) need not be assembled. Furthermore, the resilient hinge arms are preferably resilient rings or coil springs, as the hinge sections allow the resilient hinge arms to slide more easily across the surface of the structure when the mount is rotated to connect it to the structure.

The fixing member may further include a shaft, wherein one end of the shaft is provided with a connector. Additionally, the fixture may include a cap at an end of the shaft opposite the connector. The cap is arranged to retain the spare wheel during use. In particular, during use, the axle extends through the spare wheel (e.g., through a hole or opening in the spare wheel) and the connector is connected to the structure. In this position, the cap holds the spare wheel in place. The cap may be integral with the shaft or the cap may be removably connected to the shaft (e.g., by threads). Preferably, the cap and the shaft are connected by partial screw threads.

In a preferred example, the structure is part of a vehicle (e.g., an automobile). The structure may be part of the trunk (i.e., trunk) of a car, or another part of the car that stores spare wheels. The structure may be part of the vehicle chassis or may be attached (e.g., using fasteners or by a bond) to the chassis. In one example, the structure includes a mounting plate.

Preferably, the structure comprises an opening through which the fixing extends during use, and the underside of the structure comprises the recess. To connect the mount to the structure, the connector passes through an opening in the structure in a first rotational position. The opening is shaped to allow the connector to pass through in the first rotational position. The fixture is then rotated to a second rotational position in which the lug is disposed in the recess. In the second rotational position, the lug and recess connect the mount to the structure. Thus, the fixture is connected to the structure by a push-turn action. Preferably, the first and second rotational positions are separated by a rotational angle of 90 degrees, but in other examples they may alternatively be separated by other rotational amounts (e.g., a 45 degree rotational angle, a 60 degree or rotational angle, or an 18 degree rotational angle).

Preferably, the shaft comprises a shoulder, and the resilient hinge arm may extend from the shoulder in an axial direction of the shaft. In this position, the elastic articulation arm engages the structure, in particular the side of the structure facing the spare wheel.

The resilient hinge arm preferably comprises a first hinge at the junction between the resilient hinge arm and the shoulder. The first hinge is preferably resiliently flexible. Preferably, the end of the resilient hinge arm opposite the first hinge is a free end.

In a preferred example, the resilient hinge arm further comprises a second hinge portion disposed between the first hinge portion and the free end. The second hinge may be bent in a direction opposite to the first hinge. Thus, the resilient hinge arms may fold when the first and second hinge portions are bent.

In a preferred example, the fixture comprises a plurality of lugs, for example two, three or four lugs, and the structure has a corresponding plurality of recesses.

In preferred examples, the mount comprises a plurality of resilient hinge arms, for example two, three or four resilient hinge arms. The plurality of resilient hinge arms can ensure that the fixture is pushed uniformly to maintain its orientation relative to the structure (e.g., perpendicular to the structure).

In examples where the mount comprises a plurality of resilient hinged arms, each resilient hinged arm may have an angled portion (e.g., a portion between the second hinge portion and the free end as described above) that engages the structure. In such an example, the resilient hinge arm may be arranged such that the angled portion makes an acute angle with the structure in the direction of rotation of the fixture for connecting the fixture to the structure (or vice versa). In this manner, the angled portion facilitates sliding of the resilient hinge arm on the structure as the mount is rotated. In addition, if the angled portion makes an acute angle with the structure in the direction of rotation of the fixture for connecting the fixture to the structure, the resilient hinge arm may resist inversion (i.e., rotation to remove the fixture from the structure) as the resilient hinge arm may jam in such an inversion.

In some examples, to connect the mount to the structure, a user pushes the mount towards the structure to deform the or each resilient hinge arm and then rotates the mount such that the lug moves into the recess. In such an example, the surface of the structure facing the spare wheel may be planar (i.e., flat).

In some examples, the surface of the structure engaged by the or each resilient hinge arm (i.e. the surface of the structure facing the spare wheel) may be contoured to define one or more sloping segments over which the or each resilient hinge arm may slide during rotation of the mount. In one example, the structure includes for the or each resilient hinge arm a sloping section leading to the raised section. The or each resilient hinge arm will slide up the or each sloping section to the or each raised section when the fixing is connected to the structure. The or each raised section ensures that the or each resilient hinge arm is in a partially flexed condition when the fixing is connected to the structure, thereby ensuring that a biasing force is generated to retain the or each lug in the or each recess.

Preferably, the or each resilient hinge arm is an integrally moulded part of the fixing. Preferably, at least the shaft, the connector, and the or each resilient hinge arm are integrally moulded. In some examples, the fixture further includes a cap, and the cap may additionally be integrally molded with other features of the fixture.

In particular, the integral molding of these resilient hinged arms eliminates the need for a separate assembly step for the resilient member (e.g., resilient ring or coil spring).

According to another aspect of the present invention, there is also provided a securing system for securing a spare wheel to a vehicle. The fastening system comprises a structure, such as a part of a vehicle. The structure includes a recess. The fixation system further comprises a fixation member as described above. As described above, the connecting portion of the fastener is configured to engage the recess of the structure to connect the fastener to the structure.

Drawings

Exemplary embodiments of the invention are illustrated in the drawings, in which:

fig. 1 (prior art) illustrates a different design of a known securing system using vehicle securing threaded members (b), (d) to mate with corresponding threaded wheel engaging members (a), (c);

fig. 2 (prior art) illustrates another known securing system that includes (a) a plastic threaded element that may be coupled to (b), (c) a bracket or retainer secured to a vehicle structure;

fig. 3 (prior art) illustrates another known securing system in which (a) a threaded member is coupled to (b) a (metal) bracket that is permanently mounted to a vehicle structure (covered);

FIG. 4 illustrates an exploded perspective view of a vehicle spare wheel secured to a portion of a vehicle by a mount of the present invention;

figure 5 shows (a) a front view and (b) a side view of the fixture of figure 4;

FIG. 6 illustrates a close-up view of (a) a side perspective, (b) a front view, and (c) a top side perspective of the fixture of FIG. 5 when coupled to a vehicle structure, and

fig. 7 illustrates a top view of a fastening plate coupled to a vehicle structure, the fastening plate adapted to coupleably receive a connector portion of a fastener.

Detailed Description

The example embodiments described relate to a fastener or fixture for a vehicle, and in particular to a fixture for a spare wheel of a vehicle structure. However, the invention is not limited to use with vehicle components, but may be used for any suitable fastening purpose.

Certain terminology is used in the following description for convenience only and is not limiting. The words "right," "left," "lower," "upper," "front," "rear," "upward," "lower," "downward," "above," and "below" designate directions as referenced in the drawings, and are relative to the described components as assembled and as installed (e.g., in situ). The words "inner", "inwardly" and "outer", "outwardly" refer to directions toward and away from, respectively, a designated centerline or geometric center (e.g., central axis) of the described element, with the particular meaning being readily apparent from the context of the relevant description.

Further, as used herein, the terms "connected," "attached," "coupled," and "mounted" are intended to include direct connections between two members without any other members interposed therebetween, as well as indirect connections between members in which one or more other members are interposed between the aforementioned members. The terminology includes the words above specifically mentioned, derivatives thereof and words of similar import.

Further, unless otherwise specified the use of ordinal adjectives such as "first," "second," "third," etc., merely indicate that different instances of like objects are being referred to, and are not intended to imply that the objects so described must be in a given sequence, either temporally, spatially, in ranking, or in any other manner.

Throughout the specification and claims of this specification, the terms "comprise" and "comprise," and variations thereof, are to be construed as meaning "including but not limited to," and they are not intended to (and do not) exclude other moieties, additives, components, integers or steps. In the description part of the specification and claims, the singular encompasses the plural unless the context otherwise requires. In particular, where the indefinite article is used, the specification is to be understood as contemplating plurality as well as singularity, unless the context requires otherwise.

Features, integers, characteristics, compounds, chemical moieties or groups described in conjunction with a particular aspect, embodiment or example of the invention are to be understood to be applicable to any other aspect, embodiment or example described herein unless incompatible therewith. All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive. The invention is not restricted to the details of any of the foregoing embodiments. The invention extends to any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract or drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed.

Referring to fig. 4, mount 100 is used to secure spare wheel 200 to a structure 300 of a vehicle (e.g., an automobile). Typically, the structure 300 is located in the trunk (i.e., trunk) of a vehicle, such as an automobile. The structure 300 may be a portion of the floor of a vehicle trunk or may be an additional panel that is attached (e.g., fastened or joined) to the floor of the vehicle trunk or other structural members of the vehicle.

The fastener 100 extends through the central bore 202 of the spare wheel 200, but may alternatively extend through a different opening in the spare wheel 200, such as a lug bore or any other suitable opening.

As described further below, the fixture 100 includes a connector portion 102 (see fig. 5) for connecting to a corresponding connection feature 302 of the structure 300. Cap member 104 of mount 100 is configured to fixedly secure spare wheel 200 to structure 300 when connected to structure 300.

Fig. 5(a) and 5(b) show simplified front view and side view illustrations of a fixture 100 that includes a cap member 104, a shaft 106, and a connector portion 102. A shaft 106 extends between the cap member 104 and the connector portion 102.

The cap member 104 may be shaped to be held and/or gripped by a user. For example, the cap member 104 may have a groove or other configuration (not shown) that facilitates gripping of the cap member 104 by a user. The cap member 104 may be sized such that it operatively snaps over the spare wheel 200 (i.e., as shown in fig. 4, the cap member is larger than the opening 202 in the spare wheel 200). The cap member 104 may be further shaped to match a recess or other geometry of the spare wheel 200, i.e., to be disposed flush within the spare wheel 200.

Referring now to fig. 6(a) -6 (c), the shaft 106 may be threaded, and the cap member 104 may be removably coupled to the shaft 106, for example, via an internally threaded bore configured to attach to the shaft 106. In this particular exemplary embodiment, the threads on the shaft 106 are provided by partial thread segments, each thread segment extending circumferentially around only a portion of the shaft 106. The cap member 104 may have a corresponding partial internal threaded section. In this manner, the cap member 104 may be secured to the shaft 106 through rotation of less than 90 degrees (typically about 45 degrees).

In alternative examples, the cap member 104 and the shaft 106 may be integrally formed, i.e., without threads or threaded sections.

As particularly shown in fig. 4 and 6, connector portion 102 is configured to be removably connected to structure 300, and particularly to corresponding connection features 302 formed within structure 300.

In particular, the connector portion 102 has a plug 108 that extends axially away from the distal end of the shaft 106. Here, the diameter of the plug 108 is smaller than the diameter of the shaft 106 to form a shoulder 110 between the shaft 106 and the plug 110. The two lugs 112a, 112b extend transversely away from the plug 108 (i.e., radially away from the concentric shaft 106 and the longitudinal axis of the plug 108). The lugs 112a, 112b extend in opposite directions from one another to form a T-bar.

In the illustrated example, particularly shown in fig. 6(c) and 7, the structure 300 or at least a portion of the structure 300 proximate to the connection feature 302 is a planar or plate-like structure, e.g., having a thickness between 0.5mm and 5 mm. The connection feature 302 in the structure 300 may have a central opening 304 and two lateral openings 306a, 306b extending laterally from the central opening 304, which form an elongated opening within the structure 300. The openings 304, 306a, 306b are configured to allow the plug 108 and laterally extending lugs 112a and 112b to pass through the structure 300 and to the underside of the structure 300.

With particular reference to fig. 7, the underside of the structure 300 may include recesses 308a, 308b formed in an orientation perpendicular to the orientation of the lateral openings 306a and 306b and extending toward the central opening 304. The recesses 308a and 308b are configured to retainingly receive at least a portion of the lugs 112a and 112b, i.e., the recess profile may substantially match the profile of the lugs 112a, 112 b.

Further, in this particular example, the recesses 308a, 308b are formed by contours within the structure 300, i.e., the structure 300 includes bends in the sheet material to define the recesses 308a, 308b on the underside of the structure 300 (i.e., the side opposite the side on which the spare wheel 200 is placed). These folded structures also define raised areas 310a, 310b on the side of structure 300 facing spare wheel 200, as will be mentioned below.

During use, to connect the connector portion 102 to the structure 300, the connector portion 102 is pushed through the connection feature 302. In particular, the lugs 112a, 112b are aligned with the lateral openings 306a, 306b, and the plug 108 is aligned with the central opening 304. This allows the lugs 112a, 112b to move to the underside of the structure 300. The fixture 100 is then rotated (e.g., 45 degrees) to move the lugs 112a, 112b into a position aligned with the orientation of the recesses 308a, 308 b. The lugs 112a, 112b will then secure the mount 100 to the structure 300, thereby also fixedly connecting the spare wheel 200 to the structure 300.

Referring particularly to fig. 5(a) to 6(c), the fixture 100 further includes a first resilient hinge arm 114a and a second resilient hinge arm 114 b. The resilient hinge arms 114a, 114b extend from the shoulder 110 toward the respective lugs 112a, 112b (i.e., in a direction parallel to the longitudinal axis of the shaft 106). Preferably, the resilient hinge arms 114a, 114b are axially aligned with the lugs 112a, 112 b. However, those skilled in the art will appreciate that the resilient hinge arms 114a, 114b may also be arranged to be circumferentially offset relative to the orientation of the lugs 112a, 112 b. During use, the resilient hinge arms 114a, 114b are configured to biasingly engage the structure 300 to urge the mount 100 away from the structure 300 (i.e., toward the spare wheel 200) and draw (i.e., bias) the lugs 112a, 112b into the respective recesses 308a, 308 b. This biasing action acts to help retain the lugs 112a, 112b in the recesses 308a, 308b and prevent the mount 100 from rotating, thereby securing the spare wheel 200 to the structure 300.

As illustrated in fig. 6(a), each resilient hinged arm 114a, 114b has a first portion 116a, 116b extending directly from the shoulder 110. First portions 116a, 116b are connected to shoulder 110 at first hinges 118a, 118 b. The first hinges 118a, 118b are resilient and allow the first portions 116a, 116b to resiliently flex relative to the shoulder 110. Preferably, the first portions 116a, 116b extend from the shoulder 110 at a predetermined angle of about 45 degrees relative to the planar surface of the shoulder 110.

Further, each of the resilient hinge arms 114a, 114b has a second portion 120a, 120b joined to a respective distal end of the first portion 116a, 116b via a second hinge 122a, 122 b. Preferably, the second portions 120a, 120b extend at an angle of about 90 degrees relative to the orientation of the first portions 116a, 116b in a direction toward the respective lugs 112a, 112b (i.e., toward the central plane of the fastener 100) when in a non-deformed state (i.e., relaxed). The second hinges 122a, 122b allow the second portions 120a, 120b to elastically bend relative to the first portions 116a, 116 b.

In addition, each of the resilient hinge arms 114a, 114b includes a contact portion 124a, 124b formed on a distal end of the second portion 120a, 120 b. The contact portions 124a, 124b extend from the second portions 120a, 120b in a direction approximately transverse to the longitudinal axis of the concentric shaft 106 and the plug 108. As described below, the contact portions 124a, 124b are configured to engage the structure 300 to facilitate sliding movement between the resilient hinge arms 114a, 114b and the structure 300.

Each of the resilient hinge arms 114a, 114b forms a resilient biasing member (e.g., a spring member). When pressure is applied to the contact portions 124a, 124b (or the second portions 120a, 120b), the resilient hinge arms 114a, 114b will bend and fold upon themselves at the respective first 118a, 118b and second 122a, 122b hinge portions. The first and second hinge portions 118a, 118b, 122a, 122b are resilient, and the resilient hinge arms 114a, 114b exert a reaction force against such bending.

Referring now specifically to fig. 6(c), during use, when the connector portion 102 extends through the connection feature 302 in the structure 300, the resilient hinge arms 114a, 114b (and in particular the contact portions 124a, 124b and/or the second portions 120a, 120b) contact the structure 300 proximate the connection feature 302. The resilient hinge arms 114a, 114b are thereby forced to bend about their hinge portions 118, 122. When mount 100 is rotated, resilient hinge arms 114a, 114b serve to urge lugs 112a, 112b against the underside of structure 300. In particular, the resilient hinge arms 114a, 114b are used to push the lugs 112a, 112b into the recesses 308a, 308b (see fig. 7). Thus, the resilient hinge arms 114a, 114b serve to retain the lugs 112a, 112b within the recesses 308a, 308b and help secure the spare wheel 200 to the structure 300.

As best shown in fig. 5(b), the resilient hinge arms 114a, 114b have opposite orientations (i.e., curved orientations relative to a central plane of the fixture 100) such that the second portions 120a, 120b are each angled to facilitate bending/sliding as the fixture 100 rotates (e.g., clockwise). More specifically, the resilient hinge arms 114a, 114b are angled such that the second portions 120a, 120b form an acute angle with the structure 300, e.g., clockwise. In this manner, the angle of the second portions 120a, 120b helps prevent jamming and allows the resilient hinge arms 114a, 114b to bend when the mount 100 is rotated.

Referring now back to fig. 7, the connecting feature 302 of the structure 300 includes raised areas 310a, 310b disposed on either side of the open center 304. These raised features 310a, 310b may be formed by and correspond to recesses 308a, 308b formed on opposing surfaces of the structure 300. Thus, when the mount 100 is rotated such that the lugs 112a, 112b are received in the recesses 308a, 308b, the resilient hinge arms 114a, 114b engage these raised regions 310a, 310b, thereby ensuring that the resilient hinge arms 114a, 114b remain at least partially flexed to maintain the biasing action once the mount 100 is coupled to the structure 300. Preferably, the structure 300 has a respective ramp 312a, 312b leading to each raised portion 310a, 310 b. The ramps 312a, 312b facilitate the bending action of the resilient hinge arms 114a, 114b as they move to the raised areas 310a, 310 b.

Preferably, the resilient hinge arms 114a, 114b are integrally molded with the shaft 106, plug 108 and lugs 112a, 112 b. That is, the shaft 106, connector portion 102, and resilient hinge arms 114a, 114b are molded as a single component (e.g., via injection molding). Preferably, the shaft 106, connector 102 and resilient hinge arms 114a, 114b are made of a polymer material, such as Polyoxymethylene (POM). The resilient first hinge 118a, 118b and the resilient second hinge 122a, 122b of the resilient hinge arms 114a, 114b may be formed by configuring the geometry and thickness of the material, as is known in the art.

In some examples, the cap member 104 is also integrally molded with the shaft 106, the connector portion 102, and the resilient hinge arms 114a, 114 b. In other examples, the cap member 104 may be separate and subsequently attached to the shaft 106. In such examples, the cap member 104 may be made of a different material (e.g., a metal such as steel or stainless steel). In examples where the cap member 104 is separate from the axle 106 (and attached by a threaded connection as previously described) and the fixture 100 (i.e., the axle 106) may be attached to the structure 300, the spare wheel 200 may be disposed on the axle 106 such that the axle 106 extends through the hole 202 in the spare wheel 200, and then the cap member 104 is threaded onto the axle 106 to secure the spare wheel 200. The partial threads allow the cap member 104 to move axially along the shaft 106 without rotation until the cap member 104 abuts the spare wheel 200, at which point the portion of the cap member 104 rotates into engagement with the threads to secure the cap member 104 to the shaft 106.

In various examples, mount 100 may include only a single clamping lug 112 and/or only a single resilient hinge arm 114. In other examples, the fixture 100 may include more than two clamping lugs 112, for example, three or four clamping lugs 112. The profile of the opening in the structure 300 that forms the connection feature 302 may be adjusted accordingly. In other examples, fixture 100 may include more than two resilient hinge arms 114, e.g., three or four resilient hinge arms 114.

List of reference numerals:

100 fastener

102 connector part

104 cap member

106 shaft

108 plug

110 shoulder

112a, b lugs

114a, b articulated arm

116a, b first part

118a, b first hinge

120a, b second part

122a, b second hinge part

124a, b contact portion

200 spare wheel

202 center hole

300 vehicle structure

302 connection feature

304 central opening

306a, b are open laterally

308a, b recess

310a, b raised regions

312a, b ramps.