JP2021515688A - Traction elements for athletic shoes and their manufacturing methods - Google Patents

Abstract

Various embodiments are disclosed of traction elements used in athletic shoes with studs, having metal inserts extending axially from the studs, and methods of manufacturing such traction elements.

Description

The present disclosure relates generally to traction elements for shoes, in particular to traction elements for lightweight athletic shoes and methods of manufacturing such traction elements.

Traction elements for athletic shoes are used to provide a grip surface that forms traction between the sole of the shoe and the athletic ground, such as a lawn stadium. The traction element of athletic shoes commonly used in sports such as rugby uses metal studs made of metal material to adapt to the high shear forces applied to the metal studs during competition.

However, there is a demand for traction elements to reduce the weight of the traction element while satisfying all of the performance, shape specifications and material requirements required by various sports organizations.

The various aspects of the disclosure have been developed with such observations in mind, among others.

It is a top perspective view of the first embodiment of the traction element according to the aspect of this disclosure, and shows a stud body and a metal insert. It is a rear perspective view of the traction element of FIG. 1 according to the aspect of the present disclosure, and shows a metal insert extending from an internal cavity of a stud body. It is an exploded view of the traction element of FIG. 1 by the aspect of this disclosure. It is a side view of the traction element of FIG. 1 according to the aspect of this disclosure. It is a top view of the traction element of FIG. 1 according to the aspect of this disclosure. It is a bottom view of the traction element of FIG. 1 according to the aspect of this disclosure. It is sectional drawing which follows the line 7-7 of FIG. 5 of the traction element by the aspect of this disclosure. It is a top perspective view of the 2nd Embodiment of the traction element by the aspect of this disclosure, and shows the traction body and a metal insert. FIG. 8 is a rear perspective view of the traction element of FIG. 8 according to aspects of the present disclosure, showing a metal insert extending from the internal cavity of the stud body. It is an exploded view of the traction element of FIG. 8 according to the aspect of this disclosure. It is a side view of the traction element of FIG. 8 according to the aspect of this disclosure. It is a top view of the traction element of FIG. 8 according to the aspect of this disclosure. It is a bottom view of the traction element of FIG. 8 according to the aspect of this disclosure. It is sectional drawing which follows the line 14-14 of FIG. 12 of the traction element by the aspect of this disclosure. It is a top perspective view of the third embodiment of the traction element according to the aspect of this disclosure, and shows the traction body and the metal insert. FIG. 15 is a rear perspective view of the traction element of FIG. 15 according to aspects of the present disclosure, showing a steel insert extending from the cavity of the traction element. It is an exploded view of the traction element of FIG. 15 according to the aspect of this disclosure. It is a side view of the traction element of FIG. 15 according to the aspect of this disclosure. It is a top view of the traction element of FIG. 15 according to the aspect of this disclosure. It is a bottom view of the traction element of FIG. 15 according to the aspect of this disclosure. It is sectional drawing which follows the line 21-21 of FIG. 19 of the traction element by the aspect of this disclosure.

Corresponding reference characters indicate the corresponding elements between the drawings in the drawing. The headings used in the figures do not limit the scope of claims.

Various embodiments of the traction element used in athletic shoes are disclosed herein. In some embodiments, the traction element has achieved weight loss while meeting the industry's existing performance standards for athletic shoes. In some embodiments, the traction element comprises a stud body defining an internal cavity in which a metal insert is cast into the stud body and extends out of the hollow cavity. In some embodiments, the traction element comprises a stud body defining an internal cavity and a metal insert, which is mechanically coupled into the stud body and extends out of the internal cavity. In some embodiments, the metal inserts of the traction element are coupled to the sole of the athletic shoe to provide traction. Disclosed in some embodiments are methods of making a traction element in which a metal insert is cast into the stud body or is mechanically coupled to the stud body before being engaged with the sole of an athletic shoe. Will be done. In some embodiments, the metal insert includes a spherical central portion that engages the retainer of plastic or similar material within the internal cavity of the stud body when the traction element engages the athletic shoe. , Provides additional structural integrity between the metal insert and the stud body. In one aspect, the traction element meets the current standards required by public sports governing bodies, such as ROC. The ROC oversees international rugby with respect to performance, shape and material requirements set for athletic equipment such as rugby studs used in athletic shoes that include the traction elements described herein. With reference to the figures, various embodiments of the traction element used in the athletic shoe are shown, the whole of which is represented by 100, 200 and 300 in FIGS.

1 to 7 show a first embodiment of the traction element represented by reference numeral 100. In some embodiments, the traction element 100 has a roughly thimble-shaped body and a stud body 102 configured to provide traction and grip along the ground when attached to the sole of an athletic shoe. Including. In some embodiments, the stud body 102 includes a metal insert 104 that is cast into the stud body 102 at the time of manufacture and aligns along the length axis A of the stud body 102. The metal insert 104 is configured to mechanically bond the traction element 100 to the sole of the athletic shoe (not shown). In particular, with reference to FIGS. 2 to 4, 6 and 7, the stud body 102 defines the distal head portion 110 and the proximal end portion 112. In some embodiments, the proximal end portion 112 of the stud body 102 gradually inclines and extends from the distal head portion 110 and has an opening 118 that communicates with an internal cavity 120 formed within the stud body 102 during manufacturing. The peripheral flange 122 to be defined is formed. As further shown, the distal head portion 110 defines an upper end 116 of the traction element 100, which follows the sole of the athletic shoe (not shown) when the traction element 100 engages the ground or other competition ground. It is configured to provide a traction surface.

Referring to FIG. 7, in some embodiments, the metal insert 104 is made of steel and / or aluminum and is an elongated body 125 defining a distal head portion 130 cast into the stud body 102 during manufacturing. ing. Further, the distal head portion 130 connects to the shaft portion 131 of the metal insert 104, which extends between the distal cap portion 130 and the proximal thread portion 132 of the metal insert 104. As shown in the figure, the proximal thread portion 130 defines the male thread 135 to the female thread (not shown) formed within each threaded engagement point defined along the sole of the athletic shoe (not shown). It is designed to be combined. In some embodiments, the metal insert 104 further defines a spherical portion 133 formed between the shaft portion 131 and the proximal thread portion 132, which engages with a retainer or liner located within the internal cavity 120. It provides a mating surface to provide structural reinforcement between the stud body 102 and the metal insert 104. This will be discussed in more detail in relation to the traction element 200 described later.

In particular, as shown in FIGS. 4 and 5, in some embodiments, a plurality of notches 114 may be formed axially along the outer surface of the stud body 102. The plurality of notches 114 as a whole may be configured to receive a drive tool (not shown) such as a creep trench. When the drive tool engages each notch 114 and the metal insert 104 begins to fully engage the threaded engagement point along the sole of the athletic shoe, the rotation can manually rotate the stud body 102. it can. Particularly with reference to FIG. 5, in some embodiments, the stud body 102 has three notches 114A, 114B, 114C, each axially along the surface of the proximal end portion 112 of the stud body 102. It extends a certain distance and is equidistant from each other at an angle of 120 degrees. In other embodiments, two or more notches 114 may be formed to engage the cree trench when the traction element 100 is secured to the sole of the athletic shoe. In some embodiments, each notch 114 is an elongated slot configuration forming a base near the peripheral flange 122 of the stud body 102, which extends over the length of the proximal end portion 112. It gradually tapers toward the apex formed at the top of each notch 114. In another embodiment, the plurality of notches 114 may be triangular slots, square slots, symmetrical slots, asymmetric slots, circular slots, or a combination thereof.

In one method of manufacturing the traction element 100, the stud body 102 is first cast from a metal material such as aluminum, where the metal insert 104 is cast directly into the stud body 102 and the proximal threaded portion 132 of the metal insert 104 is the stud body. It is made to partially extend outward from the casting of 102. Inside the stud body 102, an internal cavity 120 is formed by hollowing out the inside of the stud body 102 around the metal insert 104, and the internal cavity 120 and the opening 118 are formed. In some embodiments, the plurality of notches 114 are formed when the stud body 102 is cast into a mold. Alternatively, the plurality of notches 114 may machine the surface of the proximal end portion 112 after the cast of the stud body 102 has been sufficiently cooled. The method of manufacturing the traction element 100 disclosed herein provides a strong structural bond between the stud body 102 and the metal insert 104, and the shearing force exerted on the traction element 100 during use breaks the metal insert 104. It does not bend or twist with respect to the stud body 102.

In one embodiment, the stud body 102 is hollowed out to form the internal cavity 120 at the time of manufacture, whereby the traction element 100 is satisfied with all the performance, shape specifications and material requirements required for a normal traction element, and the traction element is satisfied. The total weight of 100 is reduced.

In some embodiments, the traction element 100 may be manufactured with the following dimensions used during manufacture. Referring to FIG. 4, the stud body 102 may have a total length of 400 of 20.8 mm and a width of 402 of 19.4 mm. As further shown, the distal head portion 110 of the stud body 102 has a width 404 of 11.9 mm and a length of 406 of 4 mm, while the proximal end portion 112 of the stud body 102 has a length of 408 of 16. It may be 8 mm and the width 402 may be 20.8 mm. Returning to FIG. 7, the internal cavity 120 of the stud body 102 may have a length 410 of 14.6 mm, and the opening 118 of the internal cavity 120 may have a length 414 of 9.0 mm. After the metal insert 104 is cast with the stud body 102, the proximal threaded portion 132 of the metal insert 104 is centered on the longitudinal axis A of the stud body 102 and has an outward distance of 412 from the opening 118 of the stud body 102. It extends about 6.0 mm. The present disclosure contemplates that the dimensions of the stud body 102 and the metal insert 104 may vary to accommodate different shapes and sizes of traction elements used in different types of athletic shoes.

9 to 14 show a second embodiment of the traction element represented by reference numeral 200. In some embodiments, the traction element 200 has a hollow stud body 202 having a roughly thimble-shaped body configured to provide traction and grip along the ground when attached to the sole of an athletic shoe. including. In some embodiments, the stud body 202 comprises a metal insert 204 that is cast into the stud body 202 at the time of manufacture and aligns along the length axis A of the stud body 202. The metal insert 104 is configured to mechanically couple the traction element 200 to the sole of a sports shoe (not shown). In particular, with reference to FIGS. 10-10, 12, 13 and 14, the stud body 202 defines the distal head portion 210 and the proximal end portion 212. In some embodiments, the proximal end portion 212 of the stud body 202 gradually inclines and extends from the distal head portion 210 and communicates with an internal cavity 220 that defines an inner surface 224 formed within the stud body 202. A peripheral flange 222 is formed to define the opening 218 to be formed. As further shown, the distal head portion 210 defines the upper end 216 of the traction element 200, which provides a traction surface along the sole of the athletic shoe when the traction element 200 engages the ground or other competition ground. It is configured as follows.

Referring to FIG. 14, in some embodiments, the metal insert 204 is made of steel and / or aluminum and is an elongated body 225 defining a distal head portion 230 cast into the stud body 202 during manufacturing. ing. Further, the distal head portion 230 connects to the shaft portion 231 of the metal insert 204, which extends between the distal cap portion 230 and the proximal thread portion 232 of the metal insert 204. As shown, the proximal thread portion 230 defines a male thread 235 and is coupled to a female thread (not shown) formed within each engagement point defined along the sole of the athletic shoe (not shown). It is designed to do. As shown in FIGS. 9 and 14, in some embodiments, the metal insert 204 further defines a spherical portion 233 formed between the shaft portion 231 and the proximal thread portion 232, and the internal cavity 220 during manufacturing. Provide an engaging surface for contacting the retainer 206 made of a filling material such as nylon placed inside the. The retainer 206 is configured to provide additional structural reinforcement between the stud body 202 and the metal insert 204, as discussed in more detail below.

In particular, as shown in FIGS. 11 and 12, in some embodiments, a plurality of notches 214 may be formed axially along the outer surface of the stud body 202. The plurality of notches 214 as a whole may be configured to receive a drive tool (not shown) such as a creep trench. When the drive tool engages each notch 214 and the metal insert 204 begins to fully engage the sole of the athletic shoe, its rotation allows the stud body 202 to be manually rotated. In particular, with reference to FIG. 12, in some embodiments, the stud body 202 has three notches 214A, 214B, 214C, each extending axially along the surface of the proximal end portion 212. They are equidistant from each other at an angle of 120 degrees. In other embodiments, two or more notches 214 may be formed along the stud body 202 to engage the drive tool when the traction element 200 is coupled to the sole of the athletic shoe. In some embodiments, each notch 214 is formed at the base of the stud body 202 near the peripheral flange 222 and at the top of each notch 214 extending over the length of the proximal end portion 212. It forms an elongated slot structure that forms two opposing sides that gradually taper toward the apex. In another embodiment, the plurality of notches 214 may be triangular slots, square slots, symmetrical slots, asymmetric slots, circular slots, or a combination thereof.

In one manufacturing method, the stud body 202 of the traction element 200 is first cast from a metal material such as aluminum, where the metal insert 204 is cast directly into the stud body 102 and the proximal threaded portion 232 of the metal insert 204 is the stud body 202. It may extend partially outward from the casting. Inside the stud body 202, an internal cavity 220 is formed by hollowing out the inside of the stud body 202 around the metal insert 204, and the internal cavity 220 and the opening 218 are formed. Once the internal cavity 220 is formed, nylon or other type of filling material 208 forming the retainer 206 is injected, cast or inserted into the internal cavity 220 surrounding the metal insert 204 to form the stud body 202 and the metal insert 204. Provides further structural integrity between. While injecting the filling material 20 into the inner cavity 220, the spherical portion 233 is configured to provide a holding function that adds additional structural reinforcement between the stud body 202 and the metal insert 204. In some embodiments, the plurality of notches 214 are formed when the stud body 202 is cast into the mold. Alternatively, the plurality of notches 214 may machine the surface of the proximal end portion 212 after the cast of the stud body 202 has been sufficiently cooled. The method of manufacturing the traction element 200 disclosed herein provides a strong structural bond between the stud body 202 and the metal insert 204, and the shearing force applied to the traction element 200 during athletic activity causes the metal insert 204 to be formed. It will not be destroyed or bent or twisted with respect to the stud body 202.

In one aspect, as described above, by hollowing out the stud body 202 at the time of manufacture to form the internal cavity 220, all the performance, shape specifications and material requirements required for the normal traction element of the athletic shoe are made into the traction element 200. The overall weight of the traction element 200 is reduced while being filled.

In some embodiments, the traction element 200 may be manufactured with the following dimensions: Referring to FIG. 11, the stud body 202 may have a total length of 500 of 20.8 mm and a width of 502 of 19.4 mm. As further shown, the distal head portion 210 of the stud body 202 has a width 504 of 11.9 mm and a length 506 of 4.0 mm, while the proximal end portion 212 of the stud body 202 has a length 508. It may be 16.8 mm and the width 502 may be 20.8 mm. Returning to FIG. 14, the hollow cavity 220 of the stud body 202 may have a length 510 of 14.6 mm, and the opening 218 of the internal cavity 220 may have a length 514 of 9.0 mm. After the metal insert 204 is cast with the stud body 202 and the retainer 206 is placed in the internal cavity 220, the proximal threaded portion 232 of the metal insert 204 is centered on the longitudinal axis A of the stud body 204 and the stud body 202. A distance of 512 extends outward from the opening 218 of the above by about 6.0 mm. It is contemplated in the present disclosure that the dimensions of the stud body 202 and the metal insert 204 may vary to accommodate different shapes and sizes of traction elements used in different types of athletic shoes.

15 to 21 show a third embodiment of the traction element represented by reference numeral 300. In some embodiments, the traction element 300 has a roughly thimble-shaped body and a stud body 302 configured to provide traction and grip along the ground when attached to the sole of an athletic shoe. Including. In some embodiments, the stud body 302 comprises a metal insert 304 having a standard threaded or reverse threaded head. It is pushed in during manufacture and cuts into the surface of the internal cavity 320 of the stud body 302 to establish a secure engagement between the distal cap portion 330 of the metal insert 304 and the stud body 302. The details will be described later. Similar to other embodiments of the traction element 300, the metal insert 304 is configured to mechanically couple the traction element 300 to the sole of the athletic shoe (not shown). With reference to FIGS. 17-19, 20, and 21, the stud body 302 defines a distal head portion 310 and a proximal end portion 312. The proximal end portion 312 of the stud body 302 gradually inclines and extends from the distal head portion 310 to form a peripheral flange 322 defining an opening 318 communicating with an internal cavity 320 formed within the stud body 302. As further shown, the distal head portion 310 defines the upper end 316 of the traction element 300, which follows the sole of the athletic shoe (not shown) when the traction element 300 engages the ground or other competition ground. It is configured to provide a traction surface.

With reference to FIGS. 17 and 21, in some embodiments, the metal insert 304 is made of steel and / or aluminum, which extends axially from the distal cap portion 330 and the distal head portion 330. An insert body 325 that defines the position thread portion 332 is formed. As mentioned above, the distal cap portion 330 forms a male thread 350, which as a whole forms a standard or reverse threaded head, which is pushed into the internal cavity 320 of the stud body 302 during manufacture to form the distal cap. The male thread 350 of the portion 330 and the female thread 331 of the insert cut directly into the inner surface of the stud body 302 to establish a secure engagement between the distal cap portion 330 of the metal insert 304 and the stud body 302. The internal cavity 320 defines a recess 308, a first opening 318 of the stud body, a second opening 319 of the stud body, a shoulder 321 and an inner surface 324. When engaged with the stud body 302, the metal insert 304 is centered and aligned with the longitudinal axis A of the stud body 302 and partially extends outward from the internal cavity 320 of the stud body 302. As further shown, the metal insert 304 has a plurality of drive grips 333A, 333B, 333C, which are adjacent to the distal cap portion 330 of the metal insert 304 and extend radially outward from the proximal thread portion 332. It forms 333D, 333E, and 333F. The plurality of drive grips 330 are configured to engage a drive tool (not shown) that pushes the metal insert 304 into the stud body 302 and permanently engages it, as described in detail below.

In particular, as shown in FIGS. 18 and 19, in some embodiments, a plurality of notches 314 may be formed axially along the outer surface of the stud body 302. The plurality of notches 314 may be configured as a whole to receive a drive tool (not shown) such as a creep trench. When this engages the respective notch 314 and the metal insert 304 begins to fully engage the engagement point formed along the sole of the athletic shoe, the rotation of the cree trench manually rotates the stud body 302. be able to. Particularly with reference to FIG. 19, in some embodiments, the stud body 302 has three notches 314A, 314B, 314C, each axially along the surface of the proximal end portion 312 of the stud body 302. It extends a certain distance and is equidistant from each other at an angle of 120 degrees. In other embodiments, two or more notches 314 may be formed along the stud body 302 to engage the creep trench when connecting the traction element 300 to the sole of the athletic shoe. In some embodiments, each notch 314 extends at the base near the peripheral flange 322 of the stud body 302 and extends over the length of the proximal end portion 312 and is formed at the top of each notch 314. It forms an elongated slot structure that forms two opposing sides that gradually taper toward the apex. In another embodiment, the plurality of notches 314 may be triangular slots, square slots, symmetrical slots, asymmetric slots, circular slots, or a combination thereof.

In one manufacturing method, the stud body 302 of the traction element 300 may be cast from a metal material such as aluminum. The internal cavity 320 is formed by hollowing out the inside of the stud body 302 at the time of manufacturing. In another embodiment, the internal cavity 320 may be machined after cooling the stud body 302. Once the internal cavity 320 is formed, when manually pushing the metal insert 304 into the internal cavity 320 of the stud body 302, a drive tool (not shown) is used to engage the plurality of drive grips 333 of the metal insert 302. Then rotate it with the drive tool. The rotational movement of the drive tool causes the male thread 350 of the metal insert 304 to act as a standard thread head or reverse thread head, which cuts directly into the inner surface of the stud body 302 to ensure a secure engagement between the metal insert 304 and the stud body 302. Establish a match. The engagement between the metal insert 304 and the stud body 302 creates a strong structural bond between the metal insert 304 and the stud body 302, and the shearing force applied to the traction element 300 during athletic activity causes the metal insert 304 to It will not be destroyed or bent or twisted with respect to the stud body 302.

In some embodiments, the traction element 300 may be manufactured with the following dimensions used during manufacture. Referring to FIG. 18, the stud body 302 may have a total length of 600 of 15.0 mm and a width of 602 of 16.0 mm. As further shown, the distal head portion 310 of the stud body 202 has a width 604 of 12.2 mm and a length of 4.0 mm, while the proximal end portion 312 of the stud body 302 has a length of 608. It may be 12.0 mm and the width 602 may be 16.0 mm. Returning to FIG. 21, the internal cavity 320 of the stud body 302 may have a length of at least 7.5 mm, and the opening 318 of the internal cavity 320 may have a length of 614 of 13.0 mm. After the metal insert 104 is engaged with the stud body 102, the proximal threaded portion 332 of the metal insert 304 is aligned along the longitudinal axis A of the stud body 304 and is outwardly 616 distances from the opening 318 of the stud body 302. Extends about 6.5 mm. At its maximum width, the head of the metal insert 304 may have a width of 612 of 8.5 mm. It is contemplated in the present disclosure that the dimensions of the stud body 302 and the metal insert 304 may vary to accommodate different shapes and sizes of traction elements used in different types of athletic shoes.

Although specific embodiments have been illustrated and described, it should be understood from the above that various modifications can be made without departing from the spirit and scope of the invention, as will be apparent to those skilled in the art. Such changes and amendments are within the scope and teachings of the invention as defined in the claims herein.

Claims (22)

A method of manufacturing traction elements
It is a step to cast a stud body with a metal insert.
The stud body has a distal head portion and a proximal end portion.
The metal insert defines a shaft portion formed between the distal cap portion and the proximal thread portion.
The metal insert is cast with the stud body such that the proximal threaded portion of the metal insert extends axially outward by a predetermined distance from the stud body.
A step of hollowing out the proximal end portion of the stud body to form an internal cavity,
Including methods. The method of claim 1, further comprising forming a plurality of notches along the outer surface of the stud body. The method of claim 1, further comprising filling the internal cavity with a filling material to form a retainer that provides structural integrity of the metal insert to the stud body. The method of claim 3, wherein the filling material comprises a nylon material. The metal insert comprises a spherical portion formed between the shaft portion and the proximal thread portion of the metal insert and is configured to engage a retainer for holding the metal insert to the stud body. The method according to claim 3. A method of manufacturing traction elements
A step of casting a stud body having a distal head portion and a proximal end portion,
A step of hollowing out the proximal end portion of the stud body to form an internal cavity,
A step of driving the metal insert into the internal cavity to cut the metal insert into the inner surface of the internal cavity and firmly engaging the metal insert with the stud body.
Including methods. 6. The metal insert comprises a distal head portion, a proximal threaded portion, and a plurality of drive grips extending radially outward from the proximal threaded portion adjacent to the distal head portion. The method described. 7. The step of driving the metal insert into the internal cavity comprises engaging the plurality of drive grips with a drive tool and rotating the metal insert into the internal cavity. the method of. The method according to claim 7, wherein the plurality of drive grip portions include a plurality of arms extending in the radial direction. The method of claim 7, wherein the distal head portion forms a standard or reverse threaded head configured to cut into the surface of the stud body when the metal insert is engaged with the stud body. .. A hollowed-out stud body that defines the internal cavity, the distal head portion, and the proximal end portion, and a stud body that can be attached to the sole of a shoe.
With the internal cavity of the hollowed out stud body, including a lightweight filling material,
A metal insert connected to the stud body and extending axially from the stud body,
Traction element with. 11. The traction element of claim 11, wherein the stud body has a thimble shape, the thimble shape being configured to provide traction and grip strength along the ground. The traction element according to claim 11, wherein the metal insert is configured to mechanically bond the traction element to the sole of the shoe. 11. The traction element of claim 11, wherein the proximal end portion of the stud body gradually extends from the distal head portion to form a peripheral flange defining an opening communicating with an internal cavity within the stud body. The traction element of claim 11, wherein the metal insert comprises at least a steel or aluminum material. The metal insert further defines a spherical portion formed between the shaft portion and the proximal thread portion so that the spherical portion provides an engaging surface for a retainer or liner disposed within an internal cavity. The traction element according to claim 11, which is configured. The traction element according to claim 11, wherein a plurality of notches are formed in the axial direction along the outer surface of the stud body, and the plurality of notches are configured to receive a driving tool as a whole. 11. The traction element of claim 11, wherein each of the plurality of cutouts defines an elongated slot configured to form a base near the peripheral flange of the stud body. The traction element according to claim 11, wherein the plurality of cutouts define at least one of a triangular slot, a square slot, a symmetrical slot, an asymmetric slot and a circular slot. The traction element according to claim 11, wherein the metal insert is cast into the stud body. The traction element according to claim 11, wherein the metal insert is mechanically coupled to the stud body. The traction element according to claim 11, wherein the lightweight filling material comprises nylon.

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