Source: https://patents.google.com/patent/KR101688997B1/en
Timestamp: 2020-01-23 06:01:20
Document Index: 221100534

Matched Legal Cases: ['Application No. 61', 'Application No. 11', 'Application No. 11', 'Application No. 2006', 'art 890', 'Application No. 2006']

KR101688997B1 - Reel based lacing system - Google Patents
KR101688997B1
KR101688997B1 KR1020117014337A KR20117014337A KR101688997B1 KR 101688997 B1 KR101688997 B1 KR 101688997B1 KR 1020117014337 A KR1020117014337 A KR 1020117014337A KR 20117014337 A KR20117014337 A KR 20117014337A KR 101688997 B1 KR101688997 B1 KR 101688997B1
KR1020117014337A
KR20120027105A (en
마이클 조셉 닉켈
2008-11-21 Priority to US11690508P priority Critical
2008-11-21 Priority to US61/116,905 priority
2009-11-20 Application filed by 보아 테크놀러지, 인크. filed Critical 보아 테크놀러지, 인크.
2009-11-20 Priority to PCT/US2009/065405 priority patent/WO2010059989A2/en
2012-03-21 Publication of KR20120027105A publication Critical patent/KR20120027105A/en
2016-12-22 Publication of KR101688997B1 publication Critical patent/KR101688997B1/en
2019-01-18 First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=42046340&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=KR101688997(B1) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
The string tightening system selectively adjusts the size of the opening with respect to the object and causes the string in the string tightening system to be discharged incrementally. The string tightening system comprises a housing, a spool supported by the housing, and a reel including a knob supported by the housing. The reel may be configured to cause the cable to converge in a channel formed in the spool when the spool is rotated in the first direction relative to the housing and to cause the cable to be incrementally withdrawn from the spool when the spool is rotated in the second direction relative to the housing . In some embodiments, the reel may be equipped with a revolving limiter, which can be configured to prevent overheating of the cord tightening system and at the same time prevent rotation beyond a fully relaxed condition.
This application claims the benefit of U.S. Provisional Patent Application No. 61 / 116,905, filed November 21, 2008, the entirety of which is incorporated herein by reference.
In addition, the present application is related to the following documents: U.S. Patent Application No. 11 / 263,253, filed October 31, 2005 and U.S. Patent Publication No. 2006-0156517, U.S. Patent Application No. 11 / 650,665, filed on August 8, 2007, and U.S. Patent Publication No. 2007-0169378 (now pending).
Embodiments of the present invention relate to strap tightening or locking systems, and their associated parts are used alone or in combination in various articles, including lockable bags, footwear, protective clothing or other garments.
There are many devices and methods for tightening current articles. Nevertheless, there remains a need for improved apparatus and methods.
Some embodiments provide a footrest fastening system. While many of the string fastening systems described herein are described in the context of footwear, those of ordinary skill in the art will recognize that any string fastening systems described herein can be used in a wide variety of applications without undue scrutiny or alteration . For example, any of the string fastening systems disclosed herein may be used in a wide range of applications including, but not limited to, footwear, hats or other headwear, belts, gloves, helmets, backpacks or other packs, It is intended to be used in a suitcase or other suitcase, in the binding of snowboarding, water skiing or other similar objects, in a wrist rest, and in other similar or appropriate fields.
In some embodiments, the system may be configured for use with a footwear comprising first and second opposed faces adapted to fit around the foot. The opening may be disposed along the centerline of the foot, or may be offset to the side of the centerline. The plurality of string guide members may be located on opposite sides of the footwell. One or more straps (also referred to herein as cables) may be guided by guide members. The string is connected to one or more spools which are rotatable in a winding direction and incrementally rotatable in a pulling direction. The spool allows the string to be unwound incrementally from the spool.
In some embodiments, embodiments of the one or more spools disclosed herein may be used with cord tightening systems, with or without appropriate or conventional, incremental unwinding characteristics. For example, in some embodiments, embodiments of one or more of the spools disclosed herein may be used with the tightening system disclosed in U.S. Patent Publication No. 2006-0156517, which is incorporated as a reference, as if presented herein .
In some embodiments, the strap may be slidably positioned about the guide members to provide a dynamic fit in response to movement of the foot within the footwear. The guide members may have a C-shaped cross-section.
In some embodiments, the cord tightening system may have a spool supported in a cavity or opening formed in the housing, and a knob supported directly or indirectly by the housing. The spool may be arranged to receive one or both ends of the cable through the string tightening system. In some embodiments, one or both ends of the cable may be attached to the housing. The spool may be arranged to be rotatable in a first direction, a winding direction, corresponding to a user turning the knob in the first direction with respect to the housing. Additionally, the spool may be arranged to be rotatable in a second direction, a loosening direction, corresponding to a user turning the knob in the second direction relative to the housing.
In some embodiments, the strap or cable of the tightened or partially tightened strap tightening system may cause a rotational force in a second direction applied to the spool, a pulling direction. The string tightening system can be arranged such that the string is selectively incrementally unwound from the spool in the second direction, the loosening direction, as the user actuates the incremental loosening of the spool. In some embodiments, the incremental unwinding of the string may be indicated by audible noise or a recognizable physical click.
In some embodiments, the user can actuate the incremental unwinding of the spool by rotating the knob in the second direction relative to the housing, the unwinding direction, and move the arms protruding from the spool to their respective And allow the spool to rotate until the arms engage the next depression formed in the housing. The arms can be released from the constraint by deflecting the ends of the arms from the depressions. The user can continue the incremental unwinding of the spool by continuing to rotate the knob in the second direction, loosening direction with respect to the housing.
In some embodiments, the spool can be completely released relative to the housing so that the spool can freely loosen the strap (i.e., the spool can be freely rotated in the second direction, . In some embodiments, release may be facilitated by dropping the spool from the awing so that the arms protruding from the spool are no longer engaged with respective depressions formed in the housing. Once the desired number of cables have been unwound from the spool, the spool can move back to the housing so that the arms protruding from the spool are again engaged with the respective depressions formed in the housing. As a result, the spool may again be in the locked position relative to the housing to prevent the spool from freely rotating in the second direction, the unwinding direction.
In some embodiments, a cord tightening system is provided in a footwear having an upper with a side and a central surface. The cord tightening system has a first cord guide which is attached at least to the side of the upper, and a second cord guide which is attached to the center of the upper. Each of the first and second string guide portions has a strap passage, a strap slidably extending along the strap passages of the respective first and second strap guide portions. Additionally, in order to tighten the footwear, a fastening reel of the footwear which allows the strap to engage and thereby advances the first string guide in the direction of the second string guide can be located in the footwear. And the locking device can move between the coupled and un-coupled positions. Wherein the lancing device allows the lancing device to rotate only in the first, winding direction when the lancing device is engaged and allows the reel to rotate in the second, loosening direction when loosened.
Some embodiments may also include closed loop straps. Here the string can be mounted on the reel. Thus, each of the at least one first or second string guide portions has an open channel capable of receiving a closed loop strap. In some embodiments, the string is mounted on the reel so that it can be unwound.
According to an embodiment of another footwear system, the spool and cord unit comprises a spool having a ratchet teeth disposed on the outer surface to act on the arm to prevent relative rotation in at least one direction, and a string tightly attached to the spool The footwear is provided in a string fastening system. Optionally, the strap can be formed of slippery plastic with relatively low elasticity and high tension. Optionally, the strap may be a multi-strand polymer cable. Optionally, the strap may be a multi-stranded metal cable with a slippery polymer sheath.
Some embodiments provide a mechanism for tightening and loosening a string comprising a spool rotating about a central axis and a plurality of elongated members having a free end and protruding from the shaft. The mechanism may also include a housing having a plurality of teeth arranged to engage the free ends of the elongate members. When the spool is rotated in the first direction, the engagement of the free ends and the teeth prevents the spool from rotating in the opposite direction, but does not prevent rotation in the first direction so that the string is tightened and wrapped around the spool. When the spool is rotated in a direction opposite to the first direction to loosen the strap, the plurality of driving members may be arranged to move the free ends of the elongate member away from the teeth.
Some embodiments provide a mechanism for tightening and loosening a string including a spool that rotates about a central axis. The mechanism also includes a plurality of elongate members protruding from the axis and a plurality of protrusions that also protrude from the axis. Each of the elongate members has a free end. The housing also prevents engagement of the teeth with the free ends when the spool rotates in the first direction to prevent the spool from rotating in the opposite direction but does not prevent rotation in the first direction so that the strap is tightened and wound around the spool The free ends of the elongate members. A knob including a plurality of driving members having first and second driving surfaces may also be included. The first driving surface is configured to engage with the protrusions when the knob is rotated in the first direction. The second driving surface engages the free ends of the elongate members and is configured to drop the free ends of the elongate members from the teeth as the knob rotates in the opposite direction.
Some embodiments include a stop strap that prevents the spool from over tightening. The stop strap can be wound around a separate channel from the strap channel as the spool rotates to tighten the strap. The stop strap can be, for example, a channel defined by the bottom surface of the channel or spool and the base of the housing formed in the spool. The stop strap can be wound around the rotating shaft with the spool contacting. When the stop strap is tightly wrapped around the channel, the spool can be prevented from being tightened any further. By selecting an appropriate length for the stop strap, the range in which the spool can tighten the strap can be limited. In some embodiments, the length of the stop strap, which can be locked so that the spool is no longer tightened, is approximately selected by a position where the string channel of the spool is filled by the strap so that the further tightening is such that the spool does not move . In some embodiments, the stop strap can also prevent the spool from rotating in the unwinding direction after the strap has been sufficiently fully unwound.
Some embodiments provide a reel for use in a cord tightening system. The reel may include a housing having a plurality of depressions formed therein, the spool being supported by the housing. The spool may include one or more arms extending therefrom and an annular channel formed therein. The reel may also include a knob supported by the housing. The reel may be configured to collect the spool into a channel formed in the spool when the spool is rotated in the first direction relative to the housing. The reel may also be formed such that the cable is released from the channel formed in the spool when the spool is rotated in the second direction relative to the housing. In some embodiments, each of the arms extending from the spool defines an unconstrained free end. Each of the ends may be configured to selectively engage each of the plurality of depressions to prevent the spool from rotating in a second direction relative to the housing when the one or more arms are in the unlatched position . In some embodiments, each of the arms is configured to not substantially impede the rotatability of the spool in a first direction relative to the housing. The knob is configured such that when the knob is rotated in the second direction relative to the housing, each of the arms extending from the spool is disengaged with respect to each of the arms so as to release each of the arms from their respective depressions, From the &lt; / RTI &gt;
Some embodiments provide a method of collecting and draining cables to a cable reel. The method includes providing a reel comprising a housing having a plurality of depressions formed therein. The reel is supported by the housing and collects the cable around a portion of the spool when the spool is rotated in the first direction with respect to the housing and the cable is secured to the housing when the spool is rotated in a second direction opposite to the first direction relative to the housing. And a spool configured to incrementally release a constant increment. The reel may also include a knob supported by the housing. The method may also include rotating the spool in a first direction relative to the housing to wind the cable around a portion of the spool to draw a portion of the cable into the reel. The method may also include rotating the spool in a second direction opposite to the first direction relative to the housing to incrementally withdraw a constant increment of cable from the reel. In some embodiments, the rotational position of the spool relative to the housing can be selectively locked with respect to the second direction, but not with respect to the first position.
Some embodiments provide a reel for use in a string fastening system. The reel may include a housing and a spool rotatably supported on the housing. The spool may include an annular string channel formed therein, and the spool may be configured to collect the string into the annular string channel as it is rotated. The reel may further include a stop strap configured to wrap around the annular stop strap channel when the spool is rotated, and the stop strap has a length selected to prevent the strap from over winding.
Some embodiments provide a method for preventing excessive tightening of a cord tightening system. The method comprises the steps of rotating the spool relative to the housing to gather the string into an annular strap channel formed in the spool, causing the strap to wrap around the annular strap channel as the spool rotates relative to the housing, Tightening around the annular stop cord channel to prevent further rotation of the spool.
1 is a perspective view of one embodiment of a reel-based cord tightening system.
2 is a perspective view of a sports shoe including an embodiment of the reel-based strap tightening system of FIG.
Figure 3 is an exploded perspective view of one embodiment of the reel-based cord tightening system of Figure 1;
4 is a perspective view of one embodiment of a housing of one embodiment of the reel-based cord tightening system of FIG.
Figure 5 is a side view of an embodiment of the housing shown in Figure 4;
6 is a plan view of an embodiment of the housing shown in Fig.
Figure 7 is a perspective view of one embodiment of a cover member that can be coupled to an embodiment of the housing shown in Figures 4-6.
FIG. 8 is a perspective view of an embodiment of the housing shown in FIGS. 4-6 without the embodiment of the cover member shown in FIG. 7 attached, showing a portion of the string threaded through a portion of the housing embodiment;
Figure 9 is a perspective view of the bottom of another embodiment of the housing, showing a portion of the string threaded through a portion of the housing embodiment;
Figure 10 is a perspective view of an embodiment of the spool shown in Figure 3;
11 is a plan view of an embodiment of the spool shown in Fig.
Figure 12 is a bottom view of an embodiment of the spool shown in Figure 3;
Figure 13 is a perspective view of the bottom portion of the embodiment of the spool shown in Figure 3;
Figure 14 is a top view of an embodiment of the spool shown in Figure 3 mounted to the housing embodiment shown in Figure 1;
15 is an enlarged view of a portion of Fig.
Figure 16 is a bottom view of an embodiment of the spool shown in Figure 3 and shows a portion of the string supported by the spool.
Fig. 17 is a side view of an embodiment of the spool shown in Fig. 3, showing a portion of the string supported by the spool; Fig.
18 is a top perspective view of an embodiment of the knob shown in Fig.
19 is a perspective view of the bottom of an embodiment of the knob shown in Fig.
20 is a bottom view of an embodiment of the knob shown in Fig.
21 is a perspective view of an embodiment of the string tightening system shown in FIG. 1 and another embodiment of a knob that can be used.
22 is a perspective view of an embodiment of the cord tightening system shown in FIG. 1 and another embodiment of a knob that can be used.
23 is a side view of an embodiment of the cord tightening system shown in Fig.
Fig. 24 is a cross-sectional view of an embodiment of the cord tightening system shown in Fig. 1, taken at 24-24 of Fig. 23, showing a state in which the cord tightening system is rotated in a first direction;
Fig. 25 is a cross-sectional view of an embodiment of the cord tightening system shown in Fig. 1, taken at 25-25 line in Fig. 23, showing a state in which the cord tightening system is rotated in the second direction;
26 is a plan view of another embodiment of a spool that may be configured for use with any of the string fastening systems disclosed herein.
Fig. 27 is a side view of another embodiment of the cord tightening system, including an embodiment of the spool shown in Fig. 26;
28 is an exploded perspective view of several components of the cord tightening system shown in FIG.
29 is a cross-sectional view of an embodiment of the cord tightening system shown in Fig. 27, taken from line 29-29 in Fig. 27;
30 is a perspective view of an embodiment of the guide member shown in Fig.
31 is an enlarged perspective view of a part of the guide member shown in Fig.
32 is a perspective view of an embodiment of the cord tightening system shown in Fig. 1, showing the cord unfastened.
33 is a perspective view of an embodiment of the cord tightening system shown in Fig. 32, which is provided with a modified guide member.
34 is a perspective view of another embodiment of the cord tightening system, which comprises a plurality of guide members.
35 is a perspective view of one embodiment of a guide member assembly.
Figure 36 is a perspective view of a partially deployed assembly including an embodiment of the guide member assembly shown in Figure 35;
37 is an exploded perspective view of certain components of another embodiment of a cord tightening system.
38 is a cross-sectional view of the string fastening system shown in Fig.
39 is a cross-sectional view of the cord tightening system shown in Fig. 38, taken at 39-39 of Fig.
40 is a cross-sectional view of the cord tightening system shown in Fig. 38, taken at 40-40 of Fig.
41 is another cross-sectional view of the cord tightening system shown in Fig.
42 is a cross-sectional view of the cord tightening system shown in Fig. 41, taken at 42-42 of Fig.
Fig. 43 is a cross-sectional view of the cord tightening system shown in Fig. 41, taken at 43-43 of Fig.
Figure 44 is an exploded perspective view of one embodiment of a cord winder.
45 is a plan view of the string winder shown in Fig.
46 is a cross-sectional view of the string winder shown in Fig. 45, taken at 46-46 of Fig. 45;
Figure 47 is a top view of the housing part of the string winder shown in Figure 44;
Fig. 48 is a sectional view of the housing shown in Fig. 47, taken on line 48-48 of Fig. 47;
Fig. 49 is a perspective view of the housing shown in Fig. 44; Fig.
Figure 50 is a perspective view of the spring element shown in Figure 44;
51 is a perspective sectional view of a partially deployed embodiment of a knob assembly.
52 is a cross-sectional view of an embodiment of the knob assembly shown in FIG. 51, showing that the knob assembly is in the tightening mode.
53 is a cross-sectional view of an embodiment of the knob assembly shown in FIG. 51, showing that the knob assembly is in the release mode.
54A-54H are perspective views of various exemplary articles of manufacture suitable for use with any embodiment of the disclosed cord tightening system.
1 is a perspective view of one embodiment of a reel-based cord tightening system 10; 2 is a perspective view of a sports shoe including an embodiment of the reel-based strap tightening system 10 shown in FIG.
The sports shoes may be running shoes, running shoes, basketball shoes, ice skating or other active sports shoes, snowboarding boots, or any other suitable outfitter which can be tightly tightened around the wearer's foot Quot;). The string fastening system 10 may be removably mounted on the front, rear, top, sides or any suitable portion of the sport shoes. 3 is an exploded perspective view of an embodiment of the reel-based cord tightening system of FIG.
Any of the embodiments of the cord tightening system disclosed herein, or any suitable component or feature of the cord tightening system disclosed herein, may be used with any reel system or lock described in any document incorporated herein by reference, Device. &Lt; / RTI &gt; Any embodiments, components, or features of the string fastening system disclosed or implied herein may be used to create additional embodiments of the string fastening system not explicitly described herein or in the disclosures incorporated herein And forms new embodiments that are completed as part of this disclosure. Additionally, although various embodiments of string fastening systems are described herein, various elements, features, or other aspects of embodiments of the string fastening system described herein may be combined with other embodiments of string fastening systems May be combined or interchanged to form embodiments, all of which are considered to be part of this disclosure.
1-3, a string fastening system 10 includes a housing 12, a spool 14, a knob 16, a fastener 18, a string member or cable 20, and a string guide or guide member 22). As used herein, the terms cord and cable have the same meaning unless otherwise specified. As shown in Figure 2, in some embodiments, the strap tightening system 10 may be used with other strap tightening or tightening systems, including but not limited to a strap 25 and a heel strap winder May be used in conjunction with a tightening system 23 having a strap guide 21 and strap guides 24, Other suitable or preferred strap guides may be supported by the sport shoes and may be supported at any desired location to route the strap 20 and any other straps over the straps 25 or portions of the sport shoes . Typically, the housing 12, the tightening system 23, and the guides 22, 24, 26 are attached to the outer upper of the sports shoe, but the sports shoe is a sports shoe 20 in which the strap 20 can be threaded May be provided with additional guides that are supported by tongues of the tongue. In some embodiments, more or fewer string guides than the number of string guides shown in FIG. 2 can be attached to the sports shoes. One end of the strap 20 may be fixed to the housing 12 and the other end of the strap 20 may be passed through strap guides attached to the sports shoes And may be attached to the spool 16 to allow the string 20 to be tensed around the spool 16 when the knob 18 is turned. In some embodiments, the strap 25 may be omitted and the strap 20 is threaded through the guide 24 and the guide 26 so that the strap tightening system 10 guides the guide 22 to the housing 12, as well as to tighten the tightening system 23. [0035]
The strap 20 can be a low friction strap and the low friction strap can be easily balanced through the boot and / or strap guides, slid easily, and automatically extend the strap along the ankle and foot. Let's grab it. Although the embodiments are described with reference to sport shoes, the principles discussed herein can be readily applied to a wide variety of footwear, outfits, bags, tie-down devices, or other similar or suitable objects.
Generally, the straps 20 can be strained to pull the guides 22 closer to the housing 12. [ Similarly, the tightening system 23 can be tightly tensioned to pull the guides 24, 26 close to each other. Thus, reference to pulling the facing sides of the footwear toward each other here refers to that portion of the footwear designed to be pulled together to keep the footwear attached to the user &apos; s feet. Often, these portions of the footwear are disposed along a centerline on the sides of the foot. In some embodiments, access to the footwear is located away from the centerline of the footwear, for example, on the side of the centerline or behind the footwear. This reference therefore refers to a footwear which can be overlapped when the opposing edge of the footwear (e.g., tennis) and the opposite edge are pulled tightly when the opposite edge is pulled tightly against the footwear (e.g., Specific ski boots). In both cases, tight tension can be achieved by pulling the opposite sides of the footwear towards each other. As shown in Fig. 2, the strap 20 may be threaded from the housing 12 into a guide 22 located on the upper side of the sports shoe on the opposite side of the tongue of the sports shoe. As shown in FIG. 2 and as noted above, the reel-based cord tightening system 10 may be used with any other suitable or desired fastening system or systems, including, but not limited to, May be used in conjunction with the heel-mounted tightening system 23 described in more detail in PCT Application No. 2006-0156517.
As shown, the tightening system 23 may be retracted through the heel or ankle, or other portions of the sport shoes. The tightening system 23 is provided with a strap 25 which can slide through the guides 24 and 26 while tightening or tightening the strap 25 and is provided along the center line of the foot between the guides 24 and 26 A crossing pattern can be formed. In the illustrated embodiment, three guides 22, 24, 26 are attached to the sports shoes. However, any suitable number of guides may be attached to the sports shoes. In some embodiments, three, four, five, or six or more guides may be placed on each side of the boot, and each guide may be similar or different from each other. In some embodiments, one or more reel-based strap tightening systems 10 may be mounted at different locations of the shoe, and each reel-based strap tightening system may include a plurality of reel- ) And a strap.
Any of the guides including the housing 12, the tightening system 23 and the guides 22, 24 and 26 may be mounted on a sports shoe and may include but are not limited to rivets, screws, And may be mounted by any suitable fasteners or fsatening methods including adhesives or other suitable fasteners or fastening methods. As described in more detail below, the housing 12 and the guides 22, 24, 26 may be configured to adhere to any type of sports footwear, footwear or housing and other metabolites to which the guides are to be affixed, Dimensions and shapes may be defined or formed based on performance characteristics such as size, size, or other considerations. In some embodiments, it is possible to optimally control the housing 12 or the guides 22, 24, 26 to stitch directly on the outer upper of the sports shoe to distribute the force along the length of the guide. For example, when the strap 20 is subjected to a relatively high level of tension, the guides are bent, staggered, even twisted or twisted. If the tensioned guide member is bent, the frictional force between the guide member and the strap 20 can be increased, and if it is heavily bent or the guides twisted, it may undesirably interfere with the intended action of the strap tightening system. Therefore, the size, material, and shape of the housing 12 and / or guides, as well as the attachment mechanism for attaching the housing 12 and / or guides to the sports shoe, are resistant to bending and twisting of the housing 12 and guides It can be related to ability.
In some embodiments, the footrest fastening system 10 described herein may allow a user to incrementally fasten the boot around the user's foot. In some embodiments, the low friction tongue 20 associated with the low friction guide member can cause the tongue 20 to slide easily within the guide member. The strap 20 can be tensioned along the length of the strap so that the strap tightening system 10 can provide a uniform tightening pressure distribution across the foot. As will be described in greater detail below, the tightening pressure can be incrementally adjusted by turning the knob 16 relative to the housing 20. For example, in some embodiments, as described in more detail below, a user may adjust the tensioning system 10 by rotating the knob 16 in a first direction relative to the housing 12, You can make it tight. Similarly, in some embodiments, the user can incrementally loosen the strap tightening system 10 and thus the sports shoes by turning the knob 16 in a second direction relative to the housing 12. [ In some embodiments it may also be possible to actuate another release mechanism for lifting or pressing knob 16 to release the restraint of spool 14 from housing 12 or for automatically releasing string 20 from spool 14 So that the user can loosen the strap tightening system 10.
3, the spool 14 may be supported in a cavity 28 formed in the housing 10. [ As will be described in more detail below, in some embodiments, the spool 14 and the housing (not shown) are configured to rotate freely in a first direction (tightening tightening direction) relative to the housing 12 12) can be configured. Additionally, in some embodiments, the spool 14 and the housing 12 may be configured such that the spool 14 is generally freely rotatable relative to the housing 12 in a second direction (loosening direction). The knob 16 may be mechanically coupled to the housing 12 using a fastener 18 or other suitable fastener or fastening method. In some embodiments, the knob 16 may be axially constrained and free for rotation such that the knob 16 (not shown) may be rotated to allow the knob 16 to rotate freely relative to the housing 12, Can be coupled to the housing 12.
The knob 16 may be configured to drive the spool 14 in a first direction to gather the strap 20 in the spool 14 to tighten the strap tightening system 10. Additionally, the knob 16 may be moved in a second direction to cause the spool 14 to incrementally eject the gathered rope 20 to the spool 14, in order to loosen the system 10, The spool 14 can be driven to rotate. Thus, in some embodiments, the spool 14 may be configured to provide the function of gathering the strap 20 as the strap tightening system 10 is tightly tensed, and the spool 14 may also be configured to provide a strap tightening system 10 may be configured to act on the housing 12 and the knob 16 such that the strap 20 of the strap tightening system 10 is incrementally loosened when the strap 10 is loosened.
4 is a perspective view of one embodiment of the housing 12 of one embodiment of the reel-based cord tightening system of FIG. 5 and 6 are a side view and plan view, respectively, of an embodiment of the housing 12 shown in FIG. Referring to Figs. 4-6, in some embodiments, the housing 12 may include a mounting flange 30 configured to attach the housing 12 to a sports shoe. The mounting flange 30 may be configured to conform to the desired mounting method or the outline shape of the mounting fastener, the sports shoe or the object to which it is fixed, the performance characteristics of the string tightening system 10, or other factors. 5, the mounting flange 30 may be used to facilitate attachment of the housing 12 to a curved surface of a sports shoe or other object upon which the housing 12 may be mounted, for example, It can be curved. Additionally, as previously mentioned, the mounting flange 30 is configured to accommodate stitching, rivets, or other suitable or desired fastener or fastening methods for securely securing the housing 12 to a desired object, .
In some embodiments, the housing 12 may be configured to be mountable to a sports shoe or other object without the flange 30 or without the use of the flange 30. For example, in some embodiments (not shown), when the housing 12 is not provided with a flange 30, a screw or other fastener is inserted into the bottom surface of the housing 12, ) To a sports shoe or other desired object. In some embodiments, the housing 12 with the flange 30 can be attached to a sports shoe or other object using a screw.
Referring to Fig. 4, the housing 12 further includes a pair of cord entry openings 32. Fig. The cord entry openings 32 may be configured to allow the cord 20 to be threaded into the housing 12. Depending on the configuration of the desired strap tightening system 10, for example, in some embodiments, a portion (not shown) of the strap 20 wrapped around the spool 14 is threaded through the cord inlet 32a The portion of the strap 20 that enters the housing 12 through the cord inlet 32b is wound around the spool 14 when the spool 14 is rotated relative to the housing 12 (Not shown). Additionally, in some embodiments, a portion of the strap 20 (not shown) adapted to be wrapped around the spool 14 may enter the housing 12 through the strap opening 32b, The portion of the strap 20 that enters the housing 12 through the inlet 32a can be secured to the housing 12 so that it is not wrapped around the spool 14 when the spool 14 is rotated relative to the housing 12. [ have. In addition, some embodiments of the string tightening system 10 may be configured such that portions (not shown) of the strap 20 that enter both of the string inlets 32a, 32b enclose the spool 14, (14) may be a single-layer spool, a two-layer spool, or the like.
One or more of the openings 32 may be configured to provide a conduit for threading through the housing 12 such that the strap 20 is in communication with the cavity 28, . The rope 20 that is threaded into either or both of the openings 32 is threaded into the housing 12 such that the rope 20 is wound around the spool 14 as the spool 14 is rotated relative to the housing 12. [ And can be inserted into the cavity 28. Additionally, in some embodiments, one or more of the openings 32 may be configured such that the strap 20 reaches the channel or other object through the housing 12, and the channel or other object Allowing the end of the strap 20, which is not intended to be wrapped around the spool 14, to settle or otherwise adhere to the housing 12. In some embodiments, the strap tightening system 10 may be configured such that only one end of the strap 20 is attached to the housing 12.
Some embodiments of the housing 12 may include a shaft 34 projecting from the cavity 28 and provide a generally cylindrical support surface for supporting the spool 14, can do. The shaft 34 provides a support surface on which the spool 14 is freely rotatable. In some embodiments, the shaft 34 may be secured to the housing such that it is not rotated relative to the housing 12. [ However, in some embodiments, the shaft 34 may be configured to facilitate free rotation of the spool 14 relative to the housing in order to allow it to rotate freely relative to the housing 12. 4, the shaft 34 may also have an opening 36 that may be disposed generally coaxially with the longitudinal axis of the shaft 34. As shown in Fig. The opening 36 may be configured to receive a fastener 18 or other fastener used to connect the knob 16 to the housing 12. In some embodiments, the opening 36 may be threaded. In some embodiments, when the fastener 18 is threaded into the opening 34 and the threaded fastener 18, such as a fastener 18, is inserted into the opening while being rotated, The fastener 18 may be configured to be screwed into the opening 36 to secure it in the axial direction. In some embodiments, the knob 16 may be coupled to the housing 12 using a rivet made of plastic, metal, or other suitable material. In some embodiments, the fastener 18 may be ultrasonically welded to the housing 12 to attach the knob 16 to the housing 12.
Referring to FIG. 4, the housing 12 may have a generally cylindrical wall 38 that projects generally coaxially with the shaft 34. The internal space between the shaft 34 and the wall 38 defines the volume of space referred to previously as the cavity 28. [ A plurality of radially disposed notches or depressions 40 may be formed in the inner circumferential surface of the wall 38 and the depressions 40 may be formed by a series of radially arranged ratchet To form the teeth 41, which will be described in more detail below. In the illustrated embodiment, the depression 40 may define a generally triangular cross-sectional shape. However, the shape, size, or other details of the depression 40 are not limited to those shown in Fig. The depressions can be of any shape, size or other configuration suitable for controlling the rotation of the spool 14 as described herein. For example, in some embodiments, the sharp end of the ratchet teeth 41 protruding from the depression 40 may be rounded. In addition, the corners of the depressions 40 can be generally triangular or rounded.
In some embodiments, any number of depressions 40 may be formed in the wall 38. The number of depressions 40 that can be formed in the wall 30 can affect the level of adjustment of the string tightening system 10 when tightly tightened or loosened, Since the portion can provide stop positions or ratchet positions that can cause a portion of the spool 14 to stop at any of the plurality of depressions 40. [ Increasing the number of uniformly disposed depressions 40 can therefore reduce the amount of angular rotation of the spool 14 relative to the housing 12 as the spool 14 moves through each depression 40 . As the size of the housing 12 increases, the same total amount of spool 14 is retained relative to the housing 12 as the spool 14 moves from a certain depression 40 to the next depression 40 The size of the depression 40 formed in the wall 38 can be increased.
In the illustrated embodiment, generally 33 depressions 40 may be formed in the wall 38 of the housing 12. In some embodiments, between about 33 and about 40 or more depressions may be formed in the wall of the housing 12. In some embodiments, about 25 or less to about 33 depressions 40 may be formed in the walls of the housing 12. However, any desired number of depressions 40 may be formed in the housing 12. In general, the degree of adjustment can be controlled by the number of depressions 40. The greater the number of depressions, the smaller the stride of each of the spools 14 along such depressions 40, thereby reducing the amount of tension applied to the system or released from the system. Similarly, reducing the number of depressions 40 increases the distance between strides and increases the amount of tension applied to the system along with each stride or released from the system.
The angle A defining each depression 40 can be made uniform so that each depression 40 has virtually the same shape. In some embodiments, the angle A defining each depression 40 may be an obtuse angle (greater than 90 degrees), as shown in FIG. In some embodiments, the angle (A) defining each depression 40 may be an angle of about 100 degrees, an angle of between about 90 degrees or less and about 100 degrees, an angle of about 90 degrees and about 100 degrees An angle between about 100 degrees and about 110 degrees, or an angle between about 110 degrees and about 120 degrees or more. Figure 7 is a perspective view of one embodiment of a cover member 50 that can be coupled to an embodiment of the housing 12 shown in Figures 4-6. Figure 8 is a perspective view of an embodiment of the housing 12 shown in Figures 4-6 without the embodiment of the cover member 50 shown in Figure 7 attached, And shows a state in which it passes through a part. In some embodiments, the cover member 50 may be configured to substantially seal the portion of the housing adjacent to the wall 34 that provides an area for receiving the end of the strap 20, 6, as shown in Figs. The cover member 50 can be removed from the housing 12 so that the user or manufacturer can remove the strap 20 through the housing 12 to have the ability to replace the strap 20, ) To the end of the frame.
8, the strap 20 is woven through a series of three or more openings (not shown) formed in the housing 12, or the strap 20 is threaded from the housing Can be interlaced through any shape configuration that is practically suitable to prevent accidental removal. Each opening may cause the strap 22 to be deflected at an angle defined by an angle between about 30 degrees and about 100 degrees, which is sufficient to prevent the strap 20 from releasing from the housing 12 Level frictional force. In this way, one of the ends of the strap 20 can be secured to the housing 12. [ The free end of the strap 20 can be passed under a loop created by a string that weaves through three or more openings. In some embodiments, the strap 20 may be woven through a greater or lesser number of apertures to properly secure or fix the end of the strap 20 to the housing 12.
Additionally, the strap 20 may be removably or non-removably attached to the end of the strap 20 to prevent it from being knotted or the strap 20 sliding accidentally out of the housing 12, . In some embodiments, a labyrinth knot may be used to secure the end of the strap 20 to the housing 12. After the end of the strap 20 is secured sufficiently tightly to the housing 12, the cover member 50 may be removably or non-removably attached or attached to the housing. 7, cover member 50 may define protrusions 52 and protrusions 54 and protrusions 52 and protrusions 54 may define cover member 50 May be configured to engage suitable complementary features formed in the housing 12 to prevent accidental removal.
9 is a perspective view of a bottom portion of another embodiment of the housing 12 and shows a portion of the cord 20 threaded through a portion of the embodiment of the housing 12. In this embodiment, the knot 20a may be formed at the end of the strap 20 and the strap 20 may be unintentionally pulled out of the opening 32b To prevent it from being pulled out. In some embodiments, an anchor member (not shown) having a shape and size greater than the shape and size of the cross-section of the opening 32b may be attached to the end of the strap 20 and the strap 20 may be unintentional So that it is prevented from being pulled out or removed from the housing 20. For example, and not by way of limitation, a sphere or other shaped object may be formed at the end of the strap 20, and the object may be configured to prevent the strap 20 from being pulled out and removed from the housing 12 unintentionally It is the size and shape that can be made. In some embodiments, the object formed at the end of the strap 20 may be a metal ball.
In this configuration, a user may access a knot or anchor member attached to the strap 20 to replace or remove the strap 20 of the strap tightening system 10. [ 9, the user may approach the lower surface of the housing 12 to approach the knot 32a, while in some embodiments, the knot 20a may be located on the upper portion of the housing 12 The housing 20 can be configured to be accessible from a surface or an upper portion such that the user does not need to remove the housing 12 from a sports shoe or other object to remove or replace the strap 20. [ In some embodiments, the string fastening system 10 may be configured to allow any knot (e.g., but not limited to a knot 20a) or other end of the strap 20 to be accessed from above or outside the housing 12 Lt; / RTI &gt; In some embodiments, one end of the strap 20 may be attached to the housing using an adhesive and / or the other end of the strap 20 may be attached to the end of the spool 14 using an adhesive.
In some embodiments, one end of the strap 20 may be bonded to the spool 14 while the distal end of the strap 20 may be attached to the article to which the strap tightening system 10 is supported, Is attached to a portion of the object in the periphery of the housing 12 and the spool 14 such that only one end of the strap 20 passes through the housing 12 and / Be determined.
10-12 are a perspective view, a plan view and a bottom view, respectively, of a spool embodiment of the cord fastening system shown in Fig. 3; 13 is a perspective view of the bottom portion of the embodiment of the spool 14 shown in Fig. 10-11, in some embodiments, the spool 14 includes one or more driven members or protrusions 60 and one or more arms (pawls) 62 . In the illustrated embodiment, the spool 14 has three driven members 60 and three arms 62. In some embodiments, the number of arms 62 may correspond to the number of driven members 60, as shown in the illustrated embodiment. In some embodiments, the number of arms 62 may be different from the number of driven members 60. In some embodiments, the spool 14 may have fewer or greater numbers than the three driven members 60 and / or the arms 62.
Additionally, the spool 14 may have an opening 64 having a central axis substantially coincident with the symmetrical center axis of the spool 14. [ Referring to Figures 10-13, the opening 64 may be substantially cylindrical in shape and dimensioned to be slightly larger than the outer circumferential surface of the shaft 34 of the housing 12. The opening 64 of the spool 14 is positioned around the outer periphery of the shaft 34 of the housing 12 so that the spool 14 can freely rotate about the shaft 34 of the housing. 14 can be supported by the housing 12.
11, the spool 14 includes a plurality of arms 62, each of which is provided with a cantilevered tab or, on the other hand, a base 62b of the arm 62, But may be configured as a protrusion having the base 62b and an end 62a that is not supported. As such, the spool 14 may be configured to prevent each of the arms 62 from pivoting at the base portion 62b of each of the arms 62. [ Additionally, as shown in FIG. 11, the spool 14 is projected from the center point of the spool 14, which is generally circular, and projects about 90 degrees with respect to the radial line intersecting the base 62b of each of the arms 62 Each of the arms 62 may be arranged to form an angle. 11, each of the arms 62 has an angle of about 90 degrees with respect to a line L2 projected from a substantially central point of the spool 14 (each indicated by a line L1) A2), and the L2 line intersects the base portion 62b of each of the arms 62. As shown in Fig. In addition, each of the arms 62 may include one or more arms 62 that are in a relaxed state without interference from other components, such as the driven member 60, or other features of the spool 14, ), And can be dimensioned and dimensioned. [0031] As shown in Fig.
14 is a plan view of an embodiment of the spool 14 shown in Fig. 3 mounted to the cavity 28 of the embodiment of the housing 12 shown in Fig. 15 is an enlarged view of a portion of Fig. 14-15, each of the ends 62a of the arms 62 can be configured and dimensioned to rest on each of the depressions 40 formed in the wall 38 of the housing 12 (That is, the end portion 62a is configured to abut against the respective first surface 40a of the depressions 40, as shown in detail in Fig. 15). In this configuration, when each of the arms 62 is constrained to each of the depressions 40 as described above, the spool 14 is moved in a second direction (arrow D2 in Fig. 14) relative to the housing 12 Shown in Fig.
The arms 62 and the depressions 40 are positioned in the same direction as the arms 62 when the spool 14 is rotated in a first direction relative to the housing 12 Each end portion 62a can be configured and dimensioned so as not to be constrained to the respective first surface 40a of the depressions 40. [ However, in this configuration, the arms 62 may contact each of the teeth or protrusions 44 as the spool 14 rotates in the first direction D1. The arms 62 and depressions 40 allow the spool 14 to rotate generally freely in a first direction D1 to tighten the strap tightening system 10, Is configured to allow the spool 14 to gradually rotate in a second direction D2 for gradually releasing the tension of the strap tightening system 10 so as to allow gradual release on the one hand, . 15, each end 62a of the arms 62 may be configured to interface and contact each respective first surface 40a of the depressions 40, The rotation of the spool 14 in the second direction D2 relative to the housing 12 is suppressed. In some embodiments, the depressions 40 can be shaped and dimensioned such that one or more surfaces of the depressions 40 are approximately perpendicular to the longitudinal axis of the arms 62.
16 and 17 are a bottom view and a side view, respectively, of an embodiment of a spool 14 showing a portion of a strap 20 supported by a spool 14 shown in Fig. The end of the strap 20 may be attached to the spool 14 using any of a number of suitable fasteners or fastening means including those previously described in connection with attaching the strap 20 to the housing 12. [ have. 16 and 17, the end of the strap 20 is threaded through an opening 68 in the bottom portion 66 of the spool 14 and, as shown, The first channel 72 and the second channel 74 can be determined. More specifically, the strap 20 is routed through the first channel 72, then bent approximately 180 degrees, and then the end 20a of the strap 20 is inserted into the channel 72 formed in the spool 14 The rope 20 can be routed through the spool 14 to be positioned within the spool 14. In this way, the end 20a of the strap 20 can be securely fixed to the spool 14. [ However, as mentioned above, any other suitable fastener or fastening method may be used to securely fasten the strap 20 to the spool 14. [
17, the string 20 is wound around the channel 78 formed in the spool 14 when the spool 14 is rotated in the direction of tensing with respect to the housing 12 . The channel 78 may be configured to receive the strap when the strap is gathered by the spool 14. 17, the channel 78 may have a generally semicircular, "C", or "U" shaped cross-section for receiving the cord 20, or an outwardly facing A surface 79 may be provided. In the illustrated embodiment, the spool 14 may have a channel 78 configured to wrap the strap in a generally single plane or height. However, in some embodiments, the spool may have more than one channel 78, each configured to wind the strap 20 in a single plane. Additionally, in some embodiments, the size of the channel 78 can be increased to allow a plurality of heights or layers of rope 20 around the spool 14 to be wound.
Figs. 18-19 are perspective views of a planar portion and a bottom portion of an embodiment of the knob 16 shown in Fig. 1, respectively. 20 is a bottom view of an embodiment of the knob 16 shown in FIG. 18-20, in some embodiments, the knob 16 may be formed of a generally rigid body member 80, and optionally a rubber (not shown) may be provided on the surface of the knob 16 to increase gripping force on the user & A coating layer 82 may be provided.
21 is a perspective view of another embodiment of a knob 16 'that may be used with the embodiment of the string tightening system 10 shown in FIG. 22 is a perspective view of another embodiment of a knob 16 &quot; that can be used with the embodiment of the string fastening system 10 shown in Fig. Referring to Figures 21-22, in some embodiments, each of the knobs 16 ', 16' 'may comprise a rigid body member 80 and a rubber application layer 82', 82 '', (84) to increase the gripping force on the user's knobs (16 ', 16' ') or to enhance the rotational force of the user's knobs (16', 16 ''), respectively.
Each of the knobs described herein may have an opening 86 formed in the body member 80 such that it is concentric with the centerline of the knob 16. [ The opening 86 can be configured and dimensioned to receive a fastener member, such as the fastener member 18 shown in FIG. 1, for connecting the knob 16 to the housing 12. In some embodiments, the string tightening system 10 including the housing 12, the spool 14, the knob 16 and the fastener 18 is configured such that the spool 14 and the knob 16 are positioned in the With the exception that the arm 62 of the spool 14 is affected by interaction with the depression 40 formed in the housing 12 and that the spool 14 and the knob 16 are generally positioned relative to the housing 12, And can be configured to be generally axially coupled to the housing 12 by the fastener 18, while allowing it to rotate freely.
19-20, the knob 16 includes one or more protrusions or drive members 88 formed on the body member 80 to project downwardly from a generally flat bottom surface 80a of the body member 80 . 20, each of the driving members 88 is generally arc-shaped or partially cylindrically shaped, and the center line of the arc or partial cylinder is concentric with the center line of the knob 16 and the opening 86 do. Additionally, each of the drive members 88 may define a first end 88a and a second end 88b. In some embodiments, the shape and size of the first end 88a may be similar or identical to the shape and size of the second end 88b. However, in some embodiments, as in the illustrated embodiment, the shape and size of the first end 88a may be different as compared to the shape and size of the second end 88b. 20, the first end 88a of each of the drive members 88 may define a generally flat end surface, while the second end 88b of each of the drive members 88 is generally angled It is possible to define a large flat end surface.
23 is a side view of an embodiment of the cord tightening system 10 shown in FIG. Figures 24 and 25 are cross-sectional views of an embodiment of the cord tightening system shown in Figure 1, taken from lines 24-24 and 25-25, respectively, of Figure 23. Referring to Figures 24-25, a method of rotating the spool 14, a method of tightening and gradually loosening the string tightening system 10 will be described in detail.
24 shows a state in which the drive members 88 of the knob 16 and the driven members 60 of the spool 14 when the spool 14 is rotated in the first direction (indicated by the arrow D1 in Fig. 24) Describe the interaction. In particular, the string fastening system 10 is configured such that when the user rotates the knob 16 in the first direction D1, each first end 88a of the drive members 88 formed in the knob 16 The spool 14 is brought into contact with each of the driven members 60 formed on the spool 14 so that rotational force is transmitted from the knob 16 to the spool 14 to rotate the spool 14 in the first direction D1 . Each of the arms 62 formed in the spool 14 is separated from the protrusions or ratchet teeth 41 formed in the wall 38 of the housing 12 when the spool 14 is rotated in the first direction D1 And the arms 62 are sufficiently flexible against such deflection.
When the user stops rotating the knob 16 to remove the rotational force applied to the knob 16, the tension created in the tensioned string tightening system 10 forces the spool 14, In a second direction D2 loosely loosened. The string tightening system 10 may be configured to act against this loosely releasing force. In some embodiments, the string tightening system 10 is configured such that the arms 62 are constrained by the depressions 40 (as shown in FIGS. 14-15) so that the spool 14 rotates in a loosely unwinding direction Or the like. 14-15, when the arms 62 are constrained by the depressions 40, the spool 14 continues until the arms 62 are free from the constraints of the depressions 40, It can be prevented from rotating in a loosely unwinding direction. In some embodiments, the arms 62 are provided at the ends 62a of each of the arms 62 to move the ends 62a of each of the arms 62a from the depressions 40, as described below. So that it can be released from the constraint of the depressions 40.
25 shows a state in which the driving members 88 of the knob 16 and the driven member 18 of the spool 14 are rotated in the second direction (indicated by arrow D2 in Fig. 25) (60). &Lt; / RTI &gt; In particular, the string fastening system 10 is configured such that when the user rotates the knob 16 in the second direction, each second end 88b of the drive members 88 formed in the knob 16 is engaged with the spool 14 (Not shown). As the second end 88b of each of the drive members 88 formed in the knob 16 continues to apply pressure to each of the arms 62, the end 62a of each of the arms 66, The end portion 62a of each of the arms 62 passes through each of the ratchet teeth 41 formed in the housing 12 and is guided in the second direction (D2).
If the strap tightening system 10 is strained and the strap 20 is applying a rotational force to the spool 14 then the distal end 62a of the arms 62 will bend from the restrained position against the depressions 40 The string tightening system 10 can be configured such that the spool 14 rotates in the second direction D2 and each of the arms 62 is constrained to a subsequent continuous depression 40. [ 25, Fig. 25 shows a state in which each of the arms 62 has come into contact with the respective driving members 88 to release the engagement of the driving members with the depressions 40 ' (62). When the tension of the string tightening system 10 is rotated in the loosely loosening direction D2 of the spool 14, the driving members 88 bend each of the arms 62 to cause each of the arms 62 to move in the ratchet teeth 41, the strap tightening system 10 moves each of the arms 62 to the next subsequent depression 40 &quot; to be constrained biased, and then the arms 62 Can be prevented from rotating in the loosely loosening direction D2 until it is released from the restraint of the depressions 40 &quot;.
In some embodiments, as in the embodiment of the knob 16 shown in Figures 19-20, each drive member 88 may be a cut-out or a cutout formed in a portion of the drive member 88, The notch 90 can be defined. However, such removal or notch 90 is not required and may be eliminated from some embodiments of the knob 16. 19-20, an end portion 88c formed by the notch 90 may be in contact with the driven members 60 of the spool 14 for rotating the spool 14. In some embodiments, The surface can be limited. The size of the notch 90, i.e., the position of the end 88c with respect to the end 88b, can be configured to provide a desired range of knobs 16 with respect to the spool 14 that can operate without limitation.
Due to the orientation of the arms 62 in the string fastening system 10 described above, in some embodiments, the string fastening system 10 described above is only taut when the spool 14 is rotated in the first direction And may consist of a string tightening system 10 which can only be loosely loosened if the spool 14 is rotated in the opposite second direction. Therefore, in some embodiments, the spool 14 may be configured to be unidirectional. Further, the direction of the arms 62 and the position of the driven member 60 may be reversed so that the direction of tightening tension of the spool 14 relative to the housing 12 may be reversed. This configuration is also unidirectional because the string fastening system can only tense tightly by rotating the spool 14 in the second direction and can only loosely loosen by rotating the spool 14 in the first direction. However, in some embodiments, as described in more detail below, the cord tightening system may include a bi-directional spool 14 such that when the cord tightening system rotates the spool in either direction D1 or D2, .
26 is a top view of another embodiment of a spool 114 configured to be used in any of the string fastening systems disclosed herein. As described, the spool 114 shown in Fig. 26 can be used as a bi-directional spool. Any suitable strap tightening system or string fastening system disclosed herein may be configured for use with the spool 114 shown in FIG. For ease of explanation, a portion of the knob member, particularly four drive members 188, is also shown in Fig. The drive members 188 may be configured similar or identical to the drive members 88 described above with respect to the knob 16.
The embodiment of the spool 114 shown in Fig. 26 has all four arms 162, but in alternative embodiments it may have more or fewer numbers. The arms 162 are constrained to depressions formed in a housing similar to the housing 12 to prevent the spool 114 from rotating in a first direction indicated by arrow Dl in a manner similar to the arms 62 described above Lt; / RTI &gt; Arms 162 are constrained to the depressions formed in the housing (not shown) to prevent the spool 114 from rotating in a second direction, also indicated by arrow D2, in a manner similar to the arms 62 described above Configured and arranged. As will be described in detail below, the bi-directional spool 114 is provided so that the string can be gathered by the empty spool 114 regardless of whether the spool 114 is rotated in either direction D1 or D2.
Therefore, in this configuration, in order to rotate the spool 114 in the first direction D1, each of the two arms 162 'is connected to the driving member 188' (in particular, the driving members 188 ' The second ends 188b 'of the arms 162') and the arms 162 'can be disengaged from the respective depressions (not shown) that are constrained. The spool 114 is configured such that when the arms 162 'are bent by the drive members 188' of the knob (i.e., by rotating the knob, thus moving the drive members 188 ' The drive members 188 of the knob (in particular, the first end 188a of the drive members 188) rotate the spool 114 in the first direction D1 The spool 114 may be configured to be in contact with the driving members 160 formed on the spool 114. [ In this manner, the spool 114 can be gradually rotated in the first direction D1, i.e., the spool 114 can be rotated in the first direction D1 such that each of the two arms 162 is pivoted by depressions (not shown) And can be rotated in the first direction D1 until it is engaged. In some embodiments, each of the two arms 162 can be configured such that it does not substantially interfere with spool 114 rotation in a first direction, such as by moving it away from e.g. bends or depressions. However, as described above, each of the two arms 162 may be configured to substantially prevent or prevent rotation of the spool 114 in the second direction D2.
Similarly, in this configuration, in order to rotate the spool 114 in the second direction, each of the two arms 162 is moved relative to the drive member 188 of the knob (in particular, the second end of the drive members 188 188b) and the arms 162 can be disengaged from the respective depressions (not shown) that engage. The spool 114 is configured such that when the arms 162 are bent by the drive members 188 of the knob (i.e., by rotating the knob, thus moving the drive members 188 of the knob in the second direction D2 The driving members 188'of the knob are brought into contact with the driving members 160'formed on the spool 114 in order to rotate the spool 114 in the second direction D2 Can be configured to do so. In this manner, the spool 114 can be gradually rotated in the second direction D2, i.e., the spool 114 can be pivoted by depressions (not shown) each of which is followed by two arms 162 It can be rotated in the second direction D2 until it is engaged.
FIG. 27 is a side view of another embodiment of the string tightening system 210. FIG. 28 is an exploded perspective view of an embodiment of a housing 212, a spool 214, and a spring member 216 of the string tightening system 210 shown in Fig. 29 is a cross-sectional view of an embodiment of the cord tightening system shown in Fig. 27, taken from line 29-29 in Fig. 27; Any of the components of the string tightening system 210 may be similar or identical to any of the components of any other string tightening system described herein, or may include features or differences described below. In addition, any cord tightening system described herein may include any of the components or features of the cord tightening system 210 described below.
28-29, the housing 212 of the strap tightening system 210 may be configured to define an opening or channel 218 configured to receive the spring member 216. As shown in Figs. As described, the string fastening system 210 is configured to allow the spool 214 to rotate in a second direction (indicated by the arrow, D2) when the spring member 216 has not yet gathered a string on the spool 214 Lt; / RTI &gt; This may be useful for a one-way spool or cord tightening system to prevent the user from wrapping the strap in the wrong direction (i.e., in a direction that can not counteract the force applied to the spool by the tension of the strained string tightening system) .
29, the spring member 216 may be assembled with the spool 214 and the housing 212 and the first portion 216a of the spring member 216 may be formed in the housing 212 And the second portion 216b of the spring member 216 can be assembled to be received within the string collecting channel 220 formed in the spool 214. [ As with the other string fastening systems described herein, the channel 220 may be configured to define a generally semicircular, "C" or "U" shaped cross-section in which a single layer, And can be sized and sized.
29 shows a configuration in which the spring member 216 is assembled with the housing 212. The first end portion 216a of the spring member is received in the channel 218 of the housing 212, The second end 216b is assembled to be disposed within the channel 220 formed in the spool 214. [ 29 shows the string tightening system 210 before any strings are collected on the channel 220 of the spool 214. [ The spring member 216 may be biased to move toward the inner surface 220b of the channel 220 and the second end 216b of the spring member 216 may be biased May be biased to move and be constrained to the channel or deflector 224 formed in the spool 214. In some embodiments, a removal 224 is formed in the inner surface 220b of the channel 220. In some embodiments,
When the second end 216b of the spring member 216 is constrained to the removal 224 (i.e., before any strap is collected on the channel 220 formed in the spool 214), the strap tightening system 210 Prevents the spool 214 from actually rotating in the second direction D2 and prevents the spool member 214 from rotating about the second end of the spring member 216 216b may be constrained to the removal 224. In particular, the second end 216b of the spring member 216 may be configured to slide relative to the damper 224 when the spool 214 is rotated in the first direction D1. Similarly, the second end 216b of the spring member 216 is configured to prevent the spool 214 from rotating in the second direction D2 before any string is collected in the channel 220 of the spool 214 Tabs, protrusions, holes, or other features formed on the reject 224, as will be appreciated by those skilled in the art.
However, in some embodiments, the strap tightening system 210 may be configured such that when the strap is wound on the channel 220 of the spool 214 by winding the spool 214 in the first direction D1, And the second end 216b of the spring member 216 can not be restrained by the removal 224 formed in the spool 214. In this embodiment, May be configured to bend member (216). In this arrangement, as the second end 216b of the spring member 216 is bent away from the removal 224, the user releases the spring member 216 from the spring member 216 The bias of the second end 216b of the spring member 216 can then be rotated in the second direction D2 without being disturbed by the bias of the second end 216b of the spring member 216 216b may be constrained to the removal unit 224. [ In some embodiments, the spring member 216 may be biased against other portions of the sple, and may be biased against the bottom surface 220a to substantially prevent, for example, accidentally winding in the opposite direction. In some embodiments, the fixed and movable end of spring member 216 is reversed. As such, the spring member 216 may be secured to the spool 214 and optionally may be constrained to a portion of the housing 212.
30 is a cross-sectional view of an embodiment of the guide member 22 shown in Fig. 31 is an enlarged perspective view of a part of the guide member 22 shown in Fig. The guide member 22 may have a mounting flange 240 having a configuration for attaching the guide member 22 to the sports shoe shown in Fig. The mounting flange 240 may be configured to correspond to the desired mounting method or mounting fasteners, the contour shape of the sports shoe or other object to which it is to be fixed, or to meet performance characteristics or other factors of the string fastening system. For example, in some embodiments, the mounting flange 240 may be curved to facilitate attachment of the guide member 22 to the curved surface of the sports shoe or other object to which the guide member 22 is to be mounted. have. Additionally, as noted, the mounting flange 240 can be configured to receive stitches, rivets, or other suitable or desired fasteners or fastening methods for securing the guide member 22 to a desired object.
In some embodiments, the guide member 22 or any other guide member described herein may be configured to be non-useable or mountable without the flange 240 on a sports shoe or other object. For example, in some embodiments (not shown), when the guide member 22 does not include the flange 240, a screw or other fasteners may be used to attach the guide member 22 to a sports shoe or other desired object The guide member 22 can be used by being sewn on the bottom surface thereof.
In addition, referring to Figures 30-31, a channel 242 for receiving the inserted strap may be formed in the guide member 22. As shown, the channel 242 may have a generally semicircular, "C", or "U" shaped cross-section, or any suitable cross-section. In order to facilitate tensioning of the strap of the strap tightening system, the guide members 22 or, in the case of more than one, the guide members 22 are arranged along the channels 242 formed in each of the guide members 22 as the straps are strained The strap can be configured to slide easily. As shown in FIGS. 30-31, the guide member 22 may have an upper flange 246 to prevent the strap (not shown) from being unintentionally released from the channel 242. Additionally, the guide member 22 can define one or more guides 248 and can be configured to retain a strap (not shown) within the channel 242 have.
In some embodiments, the guide member 22 is positioned such that the distance between the upper surface 248a of the guide 248 and the lower surface 246a of the upper flange 246 (this gap is represented by Dg in Figure 31) (Not shown) that is received by the base portion 242 of the base plate 242. In this configuration, a strap (not shown) may be inserted into the channel 242 by forcing or pushing the strap through the space between the guide 248 and the upper flange 246, And is positioned within at least a portion of the channel 242 during operation to be biased to remain. The string can be removed in a similar manner.
Additionally, in this configuration, a loop of the strap is formed to facilitate the loosening of the strap, such that the strap can be biased such that the guide 248 is held within at least a portion of the channel 242 . For example, referring to Fig. 32, a perspective view of an embodiment of the string tightening system 10 shown in Fig. 1 shows that the strap is in a loose state and a guide 248 is provided in the portion of the channel 242 The strap 20 can be held in place by a user so that the strap 20 can be loosened from the spool (not shown) The ring 20c can be formed. Additionally, the guide 22 may be configured to allow a user to grip a portion of the strap 20 (i.e., a portion of the strap 20 that has not yet passed through the guide 22) over the shoe or other object, The guide 22 is pulled outwardly through an opening formed between the upper surface 248a of the guide 248 and the lower surface 246a of the upper flange 246 (this distance being denoted by Dg in FIG. 31) The strap 20 can be retracted.
In some configurations, the guide member 22 may be configured to limit removal or other features to assist the user in gripping the strap with a finger. One embodiment of a dispenser for assisting a user in capturing a strap is shown in Fig. 33, which is similar to the strap tightening system 10 shown in Fig. 32, As a perspective view of the embodiment, there is a difference in that a modified guide member 22 'is provided. 33, the modified guide member 22 'is provided with a removal unit 250 formed on the upper flange 246' so that the user removes the cord 20c from the channel 242 formed in the guide member 22 ' To be more easily gripped.
34 is a perspective view of another embodiment of a cord tightening system 10 &quot; having a plurality of guide members 22. As shown in Figure 34, the strap 20 can be routed through at least three separate guide members 22. In some embodiments, the first end 20a of the strap may be secured to the housing, while the second end 20b of the strap 20 may be secured to a spool (not shown) . In some embodiments, the second end 20b of the strap may be secured to the housing, while the first end 20a of the strap 20 may be attached to a spool (not shown) Can be fixed. The configuration of the various numbers of guide members 22 may be used depending on the configuration of the cord tightening system and the desired application.
In some embodiments, the strap tightening system may be configured to allow the user to quickly and easily increase or decrease the tension of the strap tightening system, for example, a guide for temporarily strapping the strap tightening system And a part of the member can be attached and removed. One example of such a configuration is described below with reference to Figures 35-36. 35 is a cross-sectional view of an embodiment of a guide member assembly 300. 36 is a partially deployed perspective assembly including an embodiment of the guide member assembly 300 shown in FIG. 35-36, an embodiment of the guide member 300 shown herein may include a base member 302 and a tab member 304. As shown in Fig. In some embodiments, the base member 302 may include a mounting flange 306, an upper flange 306, and a channel 310.
In some embodiments, the mounting flange 306 may be configured to allow the base member 302 to be attached to a sports shoe. The mounting flange 306 may be configured to conform to the desired mounting method or mounting fasteners, the contour shape of the sports shoe or other object to which it is to be fixed, the performance characteristics of the string fastening system, or other factors. For example, in some embodiments, the mounting flange 308 may have a curved surface to facilitate attachment of the base member 302 to a curved surface of a sports shoe or other object upon which the base member 302 may be mounted, . The mounting flange 308 may be configured and sized to accommodate stitching, rivets, or other suitable or desired fasteners or fastening methods for securing the base member 302 to a desired object.
In some embodiments, the base member 302 may be configured to be capable of being created on a sports shoe or other object, with or without the flange 306. For example, in some embodiments (not shown), when the base member 302 does not have the flange 306, a screw or other fastener may be used to attach the base member 302 to a sports shoe or other desired object It may be used on the bottom surface of the base member 302. [
In some embodiments, the upper flange 308 and channel 310 may be configured to receive and securely fix the connection 320 of the tab member 304. The connection 320 is similar to the inner surface of the channel 310 and can be configured to define an outer surface that replenishes the inner surface. In addition, the upper flange 308, channel 310, and / or connection 320 may be configured such that when the tab member 304 is coupled to the base member 302 once, as shown in FIG. 35, May be configured to resist or be biased against separation from being detached from the base member 302. For example, in some embodiments, the connecting portion 320 may define a first position 320a and a second position 320b separated by a distance narrower than the widest width of the channel 310, The first and second locations 320a and 320b of the first channel 320 need to be bent outwardly to be constrained to the channel 310. [ After the tab member 304 is coupled with the base member 302 such that the connection portion 320 is positioned adjacent to the channel 310, the first, second, and third positions 320a, 304 can be prevented from being separated or unintentionally removed. In addition, when tension is applied to the strap 20 by the tension of the strap tightening system, the strap 20 also applies a force to prevent the tab member 304 from being separated from the base member 302, 304). &Lt; / RTI &gt;
35-36, in some embodiments, the tab member 304 may be supported by the connection 320, attached to the connection 320, attached to the connection 320, The grip portion 322 can be defined in the recess 322. [ The grip portion 322 may be formed of a flexible rubber or web membrane, a cable loop, or other suitable material. The gripper 322 may include a feature for assisting the user to retain the grip of the gripper 322 and may include, but is not limited to, dimples, protrusions, channels, depressions 324, or other suitable features that can enhance the gripping ability of the gripper 322. [0064] Additionally, the tab member 302 may define a channel 326 configured to receive the strap 20. The channel 326 can be configured so that the strap 20 easily slips through the channel 326 while the strap tightening system is strained and relaxed.
In some embodiments, the cord tightening system can include a rotation restricting portion that can limit the amount by which the spool can be rotated relative to the housing. In some embodiments, the rotation limiter may limit rotation of the spool in both clockwise and counterclockwise directions. In some embodiments, the rotation limiter may limit the rotation of the spool between the maximum clockwise position and the maximum counterclockwise position The amount of rotation of the spool can be allowed. For example, if the spool starts at a position where the rotation restricting portion is prevented from rotating further in the clockwise direction, the spool is rotated about 4 times with respect to the housing before "locking" Six times, or another predetermined number of revolutions. Therefore, the rotation restricting portion can limit the spool to a predetermined rotation range.
Referring to Figs. 37-43, an embodiment of a cord tightening system 510 including a rotation restricting portion is described. In the illustrated embodiment, the rotation restricting portion may be a stop cord as described below. The string tightening system 510 includes a housing 512, a spool 514, a knob 516, and a fastener 518 and includes a housing 12, a spool 14, a knob 16 , And fastener 18 and are similar or identical to other housings, spools, knobs, or fasteners described herein. In addition, many of the features described in connection with the strap tightening system 510 can be incorporated into other embodiments disclosed herein. 37 is an exploded perspective view of the housing 512 and the spool 514 of another embodiment of the strap tightening system 510. Fig. For simplicity, knob 516, fastener 518, and strap 520 are not shown in FIG. 38 is a cross-sectional view of an embodiment of a string tightening system 510, showing a state close to a fully wound configuration. 39 is a cross-sectional view of an embodiment of a cord tightening system 510 taken at lines 39-39 of FIG. 40 is a cross-sectional view of an embodiment of a cord tightening system 510 taken at lines 40-40 of FIG. 41 is a short side view of an embodiment of a cord tightening system 510 and shows a state close to a fully wound configuration. 42 is a cross-sectional view of an embodiment of a cord tightening system 510 taken at 42-42 in Fig. 43 is a cross-sectional view of an embodiment of a cord tightening system 510 taken at 43-43 in FIG.
The housing 512 can include a mounting flange 530 that allows the housing 512 to be attached to a shoe or other object using stitches, rivets, screws, or other suitable fasteners . &Lt; / RTI &gt; In some embodiments, the mounting flange 530 may be omitted, and the housing may be rigidly secured to a shoe or other object, for example, secured by screws threaded into the housing 512. The housing 512 may include a cavity 528 and a shaft 534 protruding from the cavity 528. Cavity 528 and shaft 534 may be configured to support spool 514 in a manner similar to that discussed above with respect to housing 12 and spool 14 above. The shaft 534 may include an opening 536 that may be configured to receive a fastener 518 to secure the knob 516 to the housing 512 in a manner similar to that described above. In some embodiments, a substantially annular ridge portion 535 may be formed around the base of the cavity 528 and the ridge portion 535 may be formed in the spool 514 when the spool 514 is positioned in the cavity 528. In some embodiments, So that the spool 514 can be in contact with the bottom peripheral surface of the cavity 514 so that the spool 514 is spaced above the base of the cavity 528 and between the spool 514 and the base of the cavity 528, a stop cord channel 529 is formed. In the illustrated embodiment, the stop strap 531 can be wrapped around the shaft 534 as the spool 514 rotates relative to the housing 512. [ Although not shown in detail in the illustrated embodiment, the stop strap channel 529 may be formed as part of the spool 514. For example, a sprocket 514 may be used to receive the strap 520. In some embodiments, the sprocket 514 may include a strap 514, And a separate strap channel for receiving the strap 531.
The housing may include one or more cord entries 532 that may be configured to allow the cord 520 to be threaded into the housing 512. When the strap tightening system 510 is strained, the strap 520 enters the housing 512 through the inlet 532 in a manner similar to that discussed above with respect to the strap tightening system 10 and is formed in the spool 514 And can be wound around the shaft 534 in the channel 578. [ When the strap is loosened, the strap 520 can be released and can be removed from the housing through the strap inlet 532. In some embodiments, the strap tightening system 510 is configured to receive a stationary end of a strap 520 that can be tightly secured to the housing such that the strap 520 does not enter or exit the housing when strained or relaxed And a second inlet.
The housing 512 may actually have a wall 538 that is generally cylindrical in shape and that surrounds the cavity 528 and projects generally concentrically to the shaft 534. The inner surface of the wall 538 is constrained to restrain the arms 562 of the spool 514 to control the gradual rotation of the spool 514 in a manner similar to that described above with respect to the string tightening system 10, A plurality of radially positioned notches or depressions 40 may be formed to form a series of radially disposed ratchet teeth 541 that may be configured to be configured to receive a plurality of notches or depressions.
The strap tightening system 510 may include a stop strap 531 and the stop strap 531 may be configured to allow the knob 516 to be rotated in a direction that tends to tense or in a relaxed direction, . The stop strap 531 can have a first end 531 tightly fixed to the housing 512 and a second end tightly fixed to the spool 514 so that the spool 514 can rotate relative to the housing 512 The shaft 536 can be wound around the shaft 536. The first end 531a of the stop strap 531 may extend from a channel 529 formed in the cavity 528 through a hole 533 formed radially in the wall 538, A knot can be formed on the outside of the cavity 538 to prevent the first end 531a of the stopping cord 531 from being pulled into the cavity 528 through the hole 533. [ The first end 531a of the stop strap 531 can be secured to the housing in a variety of different ways. (E.g., friction created by passing the stop strap 531 through the plurality of channels in a manner similar to that described above in connection with FIG. 16), for example, by means of an adhesive, a clamp, have.
The second end 531b of the stop strap 531 may extend from the channel 529 through an aperture 535 formed axially in the spool 514 and may be formed in the top of the spool 514 Thereby preventing the second end 531b of the stopping strap 531 from being pulled into the channel 529 through the hole 535. [ The second end 531b of the stop strap 531 can be secured to the housing in a variety of different ways. (E.g., friction created by passing the stop strap 531 through the plurality of channels in a manner similar to that described above in connection with FIG. 16), for example, by means of an adhesive, a clamp, have.
The stop strap 531 may be made of any of a variety of materials including steel, monofilament, nylon, Kevlar, or other suitable material. One suitable staple material is SPECTRA TM And is manufactured by Honeywell of New Jersey Morris Township. In some embodiments, the stop strap 51 may be similar or identical in construction and dimensions or otherwise to the strap 520.
Referring to Figures 38-43, the action of the stop strap 531 will be described. 39, when the knob 516 is rotated in the direction of tension, the strap 520 is pulled into the channel 578 via the cord inlet 532 and the strap 520 is pivoted about the axis 534 ). As the additional strap 520 is pulled into the channel 578, the channel 578 becomes full. If the user continues to rotate the knob 516 while the channel 578 is full, the strap 520 may become stuck or the strap tightening system 510 may be damaged. The stop strap 531 limits the amount of strap that can be drawn into the channel 578 by limiting the amount of rotation by which the knob 516 can be rotated to prevent the strap 520 from being over- . 40, the stop strap 531 is wound around the shaft 534 in the channel 529 as the knob 516 is rotated. The stopping cord 531 may be wound tightly around the shaft 534 after a predetermined number of revolutions of the knob 516 by selecting a stopping cord 531 of an appropriate length. Once the stop strap 531 is tightly wound, the knob is prevented from being further tightened. By selecting the length of the strap 520 matching the size of the channel 578 and the size of the channel 578, the stop strap 531 can "lock" the knob when the channel is actually full. In some embodiments, the stop strap 531 may be configured to lock the knob 516 against further tension when the channel 578 still has room to accommodate the additional strap, Lt; RTI ID = 0.0 &gt; 510 &lt; / RTI &gt;
As can be seen clearly in Figure 42, when the knob 516 is rotated in the relaxed direction, the strap 520 extends from the channel 578 until the strap 520 is completely unwound around the axis 534, (532). If the user continues to rotate the knob 516 in the direction of loosening the knob 516 even if the strap 520 is completely unwound, the strap 520 begins to wrap in the opposite direction around the axis and begin to tense. In the case of a unidirectional spool configuration, the string tightening system is designed to be tensioned in one direction. Therefore, the stop strap 531 can be used to prevent the user from turning the knob 516 in a direction to relax after the strap 520 is fully relaxed. As seen in FIG. 43, as the knob 516 is rotated in the direction of relaxation, the stopping strap 531 is wound around the axis 534 in the direction opposite to that shown in FIG. By selecting an appropriate length for the stop strap 531 the stop strap 531 is tightly wrapped about the axle 534 when the strap 520 is actually fully relaxed thereby causing the knob 516 &lt; / RTI &gt; It should be understood that the stop strap can be used to lock the knob 516 against further relaxation before the strap 520 is fully relaxed and is dependent on the particular application of the strap tightening system 510. [
In the embodiment of the string tightening system 510 shown in Figs. 37-43, the spool 514 is a unidirectional bush. Thus, the stop strap 531 can be completely wrapped in the first direction when the strap 520 is actually fully released, thereby preventing the knob 516 from being further loosened, and when the channel 578 is actually filled Is fully wound in the opposite second direction, thereby preventing the knob 516 from being further strained. As a result, the stopping strap 531 can actually be released when the knob 516 is approximately halfway between the fully relaxed and fully tightened rotational positions. The number of turns of the knob between the fully tensioned position and the fully relaxed position may be approximately twice the number of turns of the stopping strap 531 around the axis 534. [ 40 and 43, the stop strap 531 may have a length that allows the stop strap 531 to wrap about twice about axis 534, It is said that the knob 516 and the spool 514 rotate four times between the tense positions. Many variations are possible with the approximate 2: 1 ratio of: For example, a longer stop strap 531 can be used that can be used to wrap around about axis 3 53, to provide approximately six turns between a fully relaxed position and a fully tensioned position.
In some embodiments, the spool may be a bi-directional spool (e.g., spool 114 of FIG. 26), and such a string tightening system may be twisted by biasing the knob in both directions. In some bi-directional embodiments, when the knob is fully tensioned in the first direction, the stop strap can be completely wrapped in the first direction and when the knob is fully tensioned in the second direction, the stop strap is completely You can wrap it. Therefore, in some bidirectional embodiments, the staple may be completely unwound at the same actual location where the strap is fully relaxed. In some bi-directional embodiments, the number of revolutions of the knob between a fully relaxed position and a fully tensioned position may be approximately equal to the number of times the stop strap can be wrapped around the axis.
Figs. 44-50 illustrate an embodiment of a string winder 600, which may be used in connection with a string fastening system, and such string fastening system 10 has been described above. As described in more detail below, the strap winder 600 may include a spring configured to maintain tension on the strap to automatically remove the strap from the strap. The strap winder 600 may also include a knob 622 configured to relax the strap when rotated in a direction that relaxes and relaxes the strap when rotated in a tensing direction.
In the illustrated embodiment, the string winder 600 includes a spool 610 that is rotatably disposed generally in the housing member 640 and is rotatably biased in a winding direction. The spool 610 is also generally coupled with a knob 622 for straining the strap by hand. Some features of the string winder 600 may be similar or identical to those of the string fastening system 10 discussed above. However, in an alternative embodiment, the features of the string winder 600 may be applied to many other desired tensioning mechanisms.
FIG. 44 is an exploded view of one embodiment of string winder 600. The embodiment of FIG. 44 illustrates a spring assembly 630, a spool assembly 632, and a knob assembly 634. Spool assembly 632 and spring assembly 630 are generally configured to be assembled together and mounted within housing 640. And the knob assembly 634 may be assembled with the housing 640 to provide a self-winding string fastening device 600. The knob assembly 634 generally includes a knob 622 and a drive gear 642 and the drive gear 642 rotates the knob 622 to a drive shaft 644 extending substantially through the entire winder 600 As shown in FIG.
Figure 45 shows a top view of the string winder 600 of Figure 44; Figure 46 is a cross-sectional view of the string winder 600 taken at lines 46-46 of Figure 45; 47 is a plan view of the housing 640 shown in Fig. Figure 48 is a cross-sectional view of the housing 640 taken at 48-48 of Figure 47; 49 is a perspective view of the housing 640 of Fig. Referring to Figures 45-49, in some embodiments, the housing 640 includes an upper section generally having a plurality of ratchet teeth 646, and the ratchet teeth 646 include arms (not shown) of the knob 622 648) (for example, as shown in Fig. 45). The housing 640 also includes a spool cavity 650 configured and dimensioned to receive the spool assembly 632 and the spring assembly 630 therein. The lower portion of the spool cavity 650 generally includes a plurality of teeth forming a ring gear 652 configured to restrain the planetary gears 654 of the spool assembly 632.
The transverse plane portion 656 generally divides the upper portion of the housing 640 from the spool cavity 650. The central aperture 658 of the transverse plane portion 656 allows the shaft 644 to extend from the knob 622 through the housing 640 and the spool assembly 632. In some embodiments, the setscrew hole 660 and / or the winding pin hole 662 may extend through the housing 640 as described in detail below. The housing 640 also includes a pair of string entry holes 664, which typically extend through the strings.
In some embodiments, a gear train may be provided between the knob 622 and the spool 610 to allow the user to apply a torsional force greater than the force exerted on the knob to the spool 610 . 44-48, such a gear train includes a plurality of planet gears 654 attached to the sun gear 670 and the spool 610, and a ring gear 650 formed on the inner circumferential surface of the housing 640, In the form of an epicyclic gear set. The described planetary gear train causes the drive shaft 644 to rotate clockwise relative to the housing 640 so that the spool 610 rotates clockwise relative to the housing 640 at a much slower speed but with a much higher torque . This provides the user with a mechanical advantage when straining the footwear cord using the device actually described. In the illustrated embodiment, the planetary gear train provides a gear ratio of 1: 4. In alternate embodiments, other gear ratios may also be used as desired. For example, any gear ratio or gear ratios between 1: 1 and 1: 5 can be used in conjunction with the foot strap tension mechanism. In some embodiments, the gear train in the string winder 600 may be omitted.
44, 46, and 48, an embodiment of a spool assembly 632 is described. Spool assembly 632 generally includes a spool body 610, a drive shaft 644, a sun gear 670, a plurality of planet gears 654, a pair of setscrews 672 and a bushing 674 do. The spool body 610 generally includes a center hole 676, a pair of setscrew holes 678, and a winding section 680 and a transmission section 682. The winding section 680 includes a pair of cord receiving apertures 684 for receiving both ends of the cord and both ends of the cord are threaded through the set screws 672 or other means as described in the previous embodiments So that it can be fixed to the spool. The cord receiving holes 684 are configured to be generally aligned with the cord entry holes 664 of the housing 640. In some embodiments, the spool body 610 also includes a winding pinhole 690 configured to receive a winding pin used during assembly, as described below. In some embodiments, the spool 610 also includes an inspection hole (not shown) that allows the user to visually confirm that the strap 23 is inserted at a sufficient distance into the spool 610 692).
The bushing 674 has an outer diameter slightly smaller than the inner diameter of the spool center hole 676. The bushing 676 also includes an inner hole 694 configured to restrain the drive shaft 644 to maintain the rotation of the bushing 674 against the drive shaft during operation of the apparatus. In the illustrated embodiment, drive shaft 644 is hexagonal and bushing 674 is hexagonal. In the illustrated embodiment, the sun gear 670 also includes a hexagon hole 702 configured to rotatably couple the sun gear 670 to the drive shaft 644. [ Optionally or additionally, the sun gear 670 and / or the bushing 674 can be securely fixed to the drive shaft 644 by press fit, key, set screw, adhesive, or other suitable method. In other embodiments, drive shaft 644, bushing 674, and / or sun gear 670 may have other cross-sectional shapes for rotationally coupling elements.
The bushing 674 is disposed within the spool hole 676 and the drive shaft 644 extends through the central bore 694 of the bushing 674 and the sun gear 670. In some embodiments, the planetary gears 654 may be supported on an axle 704 rigidly mounted to the transmission section 682 of the spool 610. Planetary gears 654 extend radially outwardly from the periphery of spool 610 and engage ring gear 652 of housing 640 when assembled to spool 610. In some embodiments, the spool transmission section 682 includes a wall 706 having apertures arranged to allow the planetary gears 654 to pass through. If desired, a plate 710 may be disposed between the planetary gears 654 and the spring assembly 630 to prevent interference between moving parts.
The spring assembly 630 generally includes a coil spring 712, a spring boss 714, and a support plate 716. In some embodiments, the spring 712 may also be disposed within the spring assembly 630 between the coil spring 718 and the spring boss 714 to prevent undesirable engagement of the spring 712 with any of the projections of the spring boss 714 A washer / plate 718 may be provided. 50 is a perspective view of an embodiment of the spring assembly 630 shown in FIG. 50, in some embodiments, spring boss 714 is tightly coupled to support plate 716 and torsion spring 712 is configured to restrain spring boss 714 in at least one rotational direction have. The coil spring 712 has an outer end 720 generally disposed on the outer periphery of the spring 712 and an inner end 722 disposed on the central portion of the spring 712. The outer end 720 is configured to be generally constrained to a portion of the spool 610. In the illustrated embodiment, the outer end 720 includes a neck for engaging a hole in a portion of the spool 610. In another alternative embodiment, the outer end 720 of the spring 712 may be securely fixed to the spool by welding, mechanical fasteners, adhesives, or other desired methods. The inner end 722 of the spring 712 includes a hooked portion configured to be connected to the spring boss 714.
The spring boss 714 includes a pair of columns 730 extending upwardly from the support plate 716. The pillars 730 are generally crescent shaped and configured to restrain the inner end 722 formed with the hooks of the spring 712 in only one rotational direction. Each post 730 includes a curved end 736 configured to receive an inner end 722 formed with a hook portion when the spring is rotated counterclockwise relative to the support plate 716. Each post 730 also includes a flattened end 738 configured to bend the inner end 722 formed with hooks when the spring 712 rotates clockwise relative to the backing plate 716. The pillars 714 and the spring 712 do not provide resistance to such rotation when the spring 712 is rotated clockwise with respect to the spring boss 714 and the support plate 716, Lt; RTI ID = 0.0 &gt; 714 &lt; / RTI &gt; On the other hand, the counterclockwise rotation of the spring 712 causes the end portion 722 with the hook portion to catch on one of the pillars 714, whereby the inner end 722 of the spring is engaged with the outer portion of the spring 712 As shown in Fig. Continuous rotation of the outer portion of the spring causes the spring to bend, thereby biasing the spring in the clockwise direction.
The space 732 between the pillars 730 of the spring boss 714 is configured and dimensioned to receive the end of the drive shaft and is free to rotate in spring boss space 732 in some embodiments shown in FIG. The end of which is configured to rotate. In the embodiment shown in Figure 44, the spring bosses 714 and the support plate 716 are shown as separately manufactured elements that are assembled later. In an alternative embodiment, the support plate 7116 and spring boss 714 may be integrally formed as a single structure and / or as part of another structure.
An embodiment of a method of assembling the self-winding string winder 600 is described with reference to Figs. The sun gear 670 and the planetary gear 654 are assembled over the transmission portion 682 of the spool 610 and the bushing 674 and the drive shaft 644 are inserted through the hole 676 of the spool 610. In this embodiment, do. The spring assembly 630 is assembled by attaching the spring boss 714 to the support plate 716 in an appropriate manner and placing the spring 712 on the spring boss 714. The outer end 720 of the spring 712 is attached to the spool 610 so that the spool assembly 632 is coupled to the spring assembly 630. In some embodiments, the spring 712 needs to be tightly wound in advance so that the spring 712 is secured within the spool wall 706. And the spool assembly 632 and the spring assembly 630 may be placed inside the housing member 640. In some embodiments, the support plate 716 may be secured to the housing member 640 by screws 740 or other suitable fasteners such as rivets, welds, adhesives, and the like.
In some embodiments, when the spool assembly 632 and spring assembly 630 are assembled and placed in the housing 640, the spring 712 may be strained before attaching the strap. 26, the spring 712 is tensioned by holding the housing 640 in a stationary state and rotating the drive shaft 644 in the direction of unwinding, whereby the bending of the spring 712 And correspondingly increases the biasing force of the spring. The winding pin 742 can be inserted through the winding pin hole 662 of the housing 640 and the winding pin hole 690 of the spool 610 when a desired degree of bending / spring bias is reached.
The winding pinhole 690 in the spool is centered relative to the winding pin hole 662 in the housing such that the setscrew hole 678 and the check hole 692 in the spool 610 When the winding pin 742 is inserted (see), it is centered with the corresponding holes 660 of the housing 640. The spool 610 and the housing 640 are also rotated so that the string receiving hole 684 of the spool 610 is aligned with the string entry hole 664 of the housing 640 when the winding pinhole 690 and the hole 662 are center- As shown in FIG. In an alternative embodiment, winding pinhole 690 and aperture 662 may be omitted and the spool may be inserted through other means, such as winding pin 742 through a setscrew hole and a hole or check hole / hole Such as by positioning it so as to position the housing in place.
When the spring 712 is strained and the winding pin 742 is inserted, it can be mounted to the spool using any suitable means provided with a strap. In the embodiment shown in Figs. 44-49, the spool 610 has a set screw 672 and is configured to secure the string to the spool. The strap can be inserted through the strap entry hole 664 of the housing 640 and through the strap receiving hole 684 of the spool 610 until the user sees the end of the strap in the appropriate check hole 692 . When the user visually confirms that the string is inserted by a sufficient distance, the set screw 672 can be tightened tightly, thereby fixing the string to the spool.
Once the strap is secured, the winding pin 742 can be removed, thereby allowing the spring to unwind or loosen the strap. And the knob 622 can be attached to the housing 640 by, for example, fixing the screw 750 to the drive shaft 644. And the user can use the knob 622 to tense the strap if desired. In an alternative embodiment, it is desirable to pre-tension the spring 712 after the string is installed on the spool 610. [ For example, if an end user wishes to change the strap in his or her footwear, the old strap can be removed by loosening the knob 622, loosening the setscrew 672 and pulling the strap have. The new strap can then be inserted through the cord entry hole 684 and secured to the spool by the set screw 672 and the knob 622 is reinstalled as described above. To tense the spring 712, the user can simply wind the string by turning the knob 622 in the winding direction only until the string is completely taut (typically without putting the foot in the dispenser) . The spring does not resist such forward windings. Because the spring boss 714 allows the spring 712 to freely rotate in the forward windings as previously described. When the strap is fully tensioned, the knob can be pulled outward, as described elsewhere herein, for example, and the strap can be pulled out. When the spool is rotated in the unwinding direction, the inner end 722 formed with the hook portion of the spring 712 is caught by the spring boss 714, and the spring is bent, thereby biasing the spool again in the winding direction.
Referring to Figures 51-53, an embodiment of an additional knob assembly 850 is described. Some embodiments of the knob assembly 850, for example a knob assembly with the string winder 600 described above, may be used. In some embodiments, the knob assembly 850 includes all of the features or parts of an embodiment of the string winder 600 described (e. G., Without magnetic winding features) May be used with a strap winder having a characteristic feature. In some embodiments, features of the knob assembly 850 may also be applied to other embodiments disclosed herein. For example, the housing 12 and knob 16 may be modified to operate in a manner similar to the knob assembly 850.
51 is a perspective sectional view of a partially deployed embodiment of the knob assembly 850. FIG. An embodiment of the knob assembly 850 shown in FIG. 51 includes a base member 850, a cover member 854, and an overmold or overlay member 856. In some embodiments, the base member 852 may be formed of a rigid or mid-rigid material and may in fact include a cylindrical outer surface 858, a substantially flat upper surface 860, A substantially flat top surface 860 and a mating portion 862 protruding from the top surface 860 in a direction substantially perpendicular to the top surface 860 and one or more mating portions 862, Taps 864. Additionally, in some embodiments, the base member 852 includes an opening 866 substantially coaxially pierced with the centerline of the base member 858, a plurality of channels and depressions 868 formed in the engagement portion 362, .
In some embodiments, the cover member 854 includes a generally planar top surface 870 and a substantially cylindrical outer wall 872 that is actually protruding perpendicularly to the top surface 870, A plurality of protrusions 874 projecting radially inwardly from the inner side 872a of the outer wall 872. The plurality of tabs 874 protrude radially inwardly from the inner side 872a of the outer wall 872. [ Additionally, an opening 878 may be formed to penetrate the top wall 870 at approximately the center of the cover member 854.
The overlay member 856 is configured to be supported by the cover member 854 and the inner circumferential surface 882 of the overlay member 856 is disposed adjacent to the outer surface of the outer wall 872. [ In some embodiments, the overlay member 856 is formed of a flexible or other suitable material, such as rubber, and the depressions 884 or other features, such as, but not limited to, channels, protrusions, dimples, taps, And other features that enhance the user's gripping force on the knob assembly 850.
51 is a cross-sectional view of an embodiment of the knob assembly 850 shown in FIG. 51 and includes a plane perpendicular to the centerline of the assembly (indicated by line CL in FIG. 51) and tabs formed on the top surface 879 of the cover member 854 Lt; RTI ID = 0.0 &gt; 874 &lt; / RTI &gt; Figure 52 shows the knob assembly 850 in a tense mode. 51 is a cross-sectional view of an embodiment of the knob assembly 850 shown in FIG. 51 and includes a plane perpendicular to another center line (indicated by line CL in FIG. 51) of the assembly and a plane perpendicular to an upper surface 870 of the cover member 854 Tabs 874, respectively. 53 shows the knob assembly 850 in the relaxed mode.
52-53, the base member 852 and the cover member 854 are disposed adjacent to the restraining tabs 864 that are supported by the base member 852 such that the tabs 874 formed on the cover member 854 As shown in FIG. When the knob assembly 850 is in the tense mode as shown in Figure 52 (i.e., when the knob assembly 850 is rotated in the first direction indicated by the arrow D1 in Figure 52), the cover member 854 The formed tabs 874 may be disposed relative to the restraint tabs 864 that are supported by the base member 852 such that the restraint tabs 864 abut against the tabs 874 of the cover member 854, . 52, each of the projections 876 formed on the tabs or the cover member 854 is restrained on each of the removed portions 890 formed in the base member 852 so that the cover member 854 (Indicated by arrow D1 in FIG. 52), the tabs 876 are brought into contact with the walls formed by the damper 890 so that the base member 852 is moved in the first direction D1). The tabs 874 formed on the cover member 854 can be urged against the constraining tabs 864 supported by the base member 852, Lt; RTI ID = 0.0 &gt; 854 &lt; / RTI &gt; As described in more detail below, when the restraint taps 864 are fully deflected outwardly by contact with the tabs 874, the knob assembly 850 is moved in the second or relaxed direction (arrow D2 And the spool engaged with the knob assembly 850 rotates the knob assembly 850 in a second direction D2 that relaxes the strap in the strap tightening system. Additionally, each of the taps or protrusions 876 formed in the cover member 854 in the relaxation mode shown in Figure 53 (i.e., when the knob assembly is rotated in the second direction D2) To turn the cover member in the second direction or in the relaxation direction D2 so that the tabs 876 come into contact with the wall forming the removal part 890, (852) is rotated in the second direction (D2).
As previously mentioned, some embodiments of the knob assembly 850 may be configured to be interchangeable with the knob 622 of the string winder 600 described above (and may be configured as described in U.S. Patent Application No. 2006-0156517 (Which will be described in more detail later in the ' 517 publication), the strap winder 600 can be configured to gradually relax. The knob assembly 850 will be discussed further below and incorporated into the string winder 600 described above. In this configuration, the knob assembly 850 is configured such that when the knob assembly is rotated in the first direction, the tension direction Dl, as described above, the knob assembly 850 is rotated about the spool assembly 600 of the string winder 600, It is possible to rotate the arm 632 in the first direction and the tension direction.
Similarly, when the knob assembly 850 is rotated in the first direction, the relaxation direction D2, as described above, the restraining tabs 874 of the cover member 854 are moved in the first direction, And the free ends 864a of the constraining taps 864 may cause the racquet teeth 646 of the string winder 600 (Figures 45, 47, 49 So that the knob assembly 850 can rotate the spool assembly 632 of the string winder 600 in the first direction, the relaxation direction. In this manner, the strap winder 600, or other reel or strap tightening system, can be configured to allow gradual relaxation in the strap tightening system.
In this configuration, the knob assembly 850 acts to move the spool assembly 632 of the string winder 600 and the knob assembly 850 from the strap that is applied to the strained or partially strained strap tightening system to the spool assembly 632 It is possible to receive a rotational force bias that tends to rotate in the second direction, the relaxation direction D2 due to the tensile force. The restraint taps 864 supported by the base member 852 of the knob assembly 850, in order to counteract the above-mentioned bias and prevent rotation of the spool assembly 632 in the second direction, i.e., The spool assembly 632 of the string winder 600 may be constrained to the ratchet teeth 646 of the string winder 600 to prevent or inhibit further rotation in the second direction, i.e. in the relaxed direction. Additionally, in some embodiments, the knob assembly 850 may be configured to be axially movable relative to the spool assembly 632 of the string winder 600, and the knob assembly 850 may be configured such that, The restraining taps 864 of the knob assembly 850 are moved away from the spool assembly 632 of the string winder 600 when the knob assembly 850 is moved far enough away from the spool assembly 632 of the string winder 600, Can be moved so as not to contact the ratchet teeth 646 of the string winder 600 so as to freely rotate in the second direction, i.e., the relaxation direction.
54A-54H are perspective views of various articles of manufacture suitable for use with any embodiment of the string fastening system described herein, and include, without limitation, the strap tightening system 10, or the components of various strap tightening systems described herein And any combination thereof. 54A, the string fastening system 10 or other string tightening system described herein may be used to control at least the tightness of the shoe around at least the ankle of the user's body, Lt; / RTI &gt; As shown therein, embodiments of strap tightening systems can be used with conventional strap tightening systems.
54B, the strap tightening system 10 or any strap tightening system described herein may be configured for use with a helmet such as that shown in FIG. 54B, for example, to control at least the tightness of the strap portion of the helmet . 54C, the strap tightening system 10 or any strap tightening system disclosed herein may be configured for use with a hat, such as that shown in FIG. 54C, for example, to control at least the tightness of the strap portion of the hat .
54D, the strap tightening system 10 or any strap tightening system described herein may be used to control the tightness of at least the glove around the wrist of a user &apos; s body, for example, to be used with a glove as shown in FIG. Lt; / RTI &gt;
54E, the cord tightening system 10, or any cord tightening system described herein, may be used to control the tightness of at least the backpack or fluid hydration carrier, Or may be configured for use with a fluid hydration carrier.
54F, the cord tightening system 10 or any cord tightening system described herein may be configured for use with a belt such as that shown in FIG. 54F to control the tightness of the belt, for example around the user's body . 54F, the strap tightening system 10 may be configured such that the strap 20 is removably supported by the guide member 22. In the embodiment of Fig.
54G, the strap tightening system 10 or any strap tightening system described herein may be used to adjust the tension of at least the cuff support around a portion of the user's arm, for example, , Cuffs, castings or other suitable objects (collectively referred to as cuffed areas).
54H, the strap tightening system 10 or any strap tightening system described herein can be configured for use with a restraint system for snowboarding, water skiing, or other suitable objects, May be configured for use with the restraint system shown in Figure 54H to regulate at least the expansion of the constraint in relation to the foot.
The components of the string fastening system described herein may be formed of any suitable material, such as, but not limited to, plastic, carbon or other fiber reinforced plastic, aluminum, steel, rubber, or other suitable materials or combinations of such materials. In some embodiments, the housing, spool, knob, string guide, or any other suitable components described herein may be formed from injection molding or other suitable polymeric materials such as nylon, PVC or PET. Some of the components described herein may be formed of slippery plastics such as PTFE or other materials that can be determined by plate testing and those parts that are capable of reducing friction between the strings are desirable. Additionally, some of the components described herein may be coated or layered with a slippery material to reduce friction with the interacting component or portion.
In some embodiments, the rope or cable (disclosed in some embodiments as a staple) may be a cable with high slip properties or a fiber having a low modulus of elasticity and high tensile strength. In some embodiments, the cable may have multiple strands of material woven together. Although any suitable strap may be used, some embodiments may utilize straps formed of high modulus polyethylene fibers of an extended chain. One example of a suitable cord material is sold under the trade name SPECTRA TM , which is manufactured by Honeywell of Morris Township, New Jersey, USA. The elongated, high modulus polyethylene fibers advantageously have a high strength to weight ratio, excellent durability, and very low elasticity. The preferred strap made of this material is woven tightly. A tightly woven string adds rigidity to the finished string. The added stiffness provided in the woven increases the pushing performance and the strap is easily threaded through the strap guide to be inserted into the reel and spool or to form a loop of strap that can be easily grasped by the user through the guide. Additionally, in some embodiments, the string may be formed of a monofilament polymer made in a mold. In embodiments involving a stop strap, the stop strap may be made using any of the materials or methods described above with respect to the strap or cable.
The string or cable may have a diameter of at least 0.02 inches and / or no more than about 0.04 inches, or at least about 0.025 inches and / or no more than 0.035 inches, and diameters beyond this range may also be used. In some embodiments, the stop strap may have a diameter within the same range provided for the strap or cable. In some embodiments, the stop strap may have a smaller diameter than the strap. The stop strap may have a diameter of at least about 0.01 inch and / or about 0.03 inch or less. In some embodiments, the stop strap may have a diameter in excess of the range provided.
Although discussed in terms of footwear including, but not limited to, ski boots, snow boots, ice skates, riding boots, hiking, running shoes, running shoes, specializing and training shoes, the string fasteners disclosed herein also include a myriad of other various applications It can provide an effective and efficient lock selection in the field. Such applications may include use in locking or ancillary systems and may include backpacks and other similar products, waistlines and / or sleeves of belts, pants and jackets, helmet neck and headband, gloves, water sports , Snow sports, and other extreme sports, or in situations where two objects are drawn together.
Although a person skilled in the art will appreciate that the present disclosure extends beyond other disclosed embodiments to other alternative embodiments and / or uses and extends to obvious improvements and their equivalents, Should be understood. Additionally, although a number of variations have been disclosed and described in detail, other modifications within the scope of this disclosure will become readily apparent to those skilled in the art based on this disclosure. It should be understood that various combinations and subcombinations of the specific features and aspects of the embodiments may be made and fall within the scope of the disclosure. It is, therefore, to be understood that various features and aspects of the disclosed embodiments may be combined or substituted with one another. It is therefore to be understood that the scope of the present disclosure is not limited to the specific embodiments disclosed above.
1. A reel for use in a string fastening system for fastening an article,
A housing having a cavity, which is an internal space defined by the wall and the wall, and a plurality of depressions formed on the surface of the wall;
A spool supported in a cavity of the housing, the spool being rotatable in a cavity of the housing and having an annular channel formed in the spool body and at least one arm extending from the spool body, A spool configured to collect a string or cable into the spool,
A knob configured to be rotatable relative to the housing and configured to drive the spool within a cavity of the housing,
Wherein rotation of the knob in a first direction relative to the housing drives the spool so that the spool collects a strap or cable on the spool to tighten the strap tightening system,
Rotation of the knob in a second direction relative to the housing separates the arm from the depression to incrementally release the string or cable gathered on the spool to increment the string tightening system The spool is driven so as to loosen the spool,
The engagement of the arms with the depressions prevents the strings or cables gathered on the spool from unwinding,
And the spool can be unlocked such that the spool can be freely rotated in the second direction to freely discharge the strap or cable.
Wherein the reel is configured not to interfere with rotation of the spool in a first direction relative to the housing and is configured to impede rotation of the spool in a second direction relative to the housing.
Wherein said spool is unlocked by axially moving said knob relative to said spool along an axis of rotation of said knob.
Said spool being unlocked by axially moving said knob relative to said housing along an axis of rotation of said knob.
And the knob can be lifted to release the restraint of the spool from the housing.
Wherein the spool is fully releasable from the housing such that the spool can be freely rotated in the second direction.
And a rotation restricting portion for restricting rotation of the spool in the second direction after the strap or cable is completely loosened.
Wherein the rotation restricting portion includes a stopper string coupled to the spool.
A method for collecting and discharging a reel string or cable used in a string fastening system for fastening an article,
A housing having a cavity, which is an internal space defined by a wall and a wall thereof, and a plurality of depressions formed on a surface of the wall; a spool supported in a cavity of the housing, the spool being rotatable in a cavity of the housing, A spool including an annular channel formed in the body and at least one arm extending from the spool body; a knob rotatable relative to the housing and configured to drive the spool in the cavity, Providing a reel configured to unlock the spool so that the spool can freely rotate in a second direction to freely eject the string or cable;
Rotating the knob to drive the spool in a first direction so that the spool collects a strap or cable on the spool to tighten the strap tightening system;
Separating the arm from the depression to drive the spool in the second direction to incrementally loosen the string tightening system by incrementally ejecting a string or cable gathered on the spool, Rotating the knob,
Preventing the arms and the recesses from engaging the string or cable gathered on the spool,
And unlocking the spool so that the spool can be freely rotated in the cavity in the second direction for freeing the spool to release the spool or cable.
The spool collecting and releasing the unlocked reel cable by moving the knob axially with respect to the spool along an axis of rotation of the knob.
The spool collecting and releasing the unlocked reel cable by moving the knob axially along the rotational axis of the knob relative to the housing.
Wherein the spool is fully releasable from the housing such that the spool can be freely rotated in the second direction when the lock is released.
Wherein the reel further comprises a rotation restricting portion for restricting rotation of the spool in the second direction after the strap or cable is completely unwound.
KR1020117014337A 2008-11-21 2009-11-20 Reel based lacing system KR101688997B1 (en)
US11690508P true 2008-11-21 2008-11-21
US61/116,905 2008-11-21
PCT/US2009/065405 WO2010059989A2 (en) 2008-11-21 2009-11-20 Reel based lacing system
KR20120027105A KR20120027105A (en) 2012-03-21
KR101688997B1 true KR101688997B1 (en) 2016-12-22
ID=42046340
KR1020117014337A KR101688997B1 (en) 2008-11-21 2009-11-20 Reel based lacing system
US (5) US8468657B2 (en)
EP (2) EP2805639B1 (en)
KR (1) KR101688997B1 (en)
WO (1) WO2010059989A2 (en)
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2009-11-20 EP EP14168875.4A patent/EP2805639B1/en active Active
2009-11-20 EP EP20090760413 patent/EP2378911B1/en active Active
2009-11-20 KR KR1020117014337A patent/KR101688997B1/en active IP Right Grant
2009-11-20 WO PCT/US2009/065405 patent/WO2010059989A2/en active Application Filing
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US10123589B2 (en) 2018-11-13
US20190069641A1 (en) 2019-03-07
US20150101160A1 (en) 2015-04-16
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US20160198803A1 (en) 2016-07-14
US8468657B2 (en) 2013-06-25
US20130277485A1 (en) 2013-10-24
US20100139057A1 (en) 2010-06-10
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US9138030B2 (en) 2015-09-22
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