U.S. patent application number 09/765867 was filed with the patent office on 2002-07-18 for snowboard boot with removable forward support.
Invention is credited to Hall, William B., Martin, John D..
Application Number | 20020092205 09/765867 |
Document ID | / |
Family ID | 25074721 |
Filed Date | 2002-07-18 |
United States Patent
Application |
20020092205 |
Kind Code |
A1 |
Hall, William B. ; et
al. |
July 18, 2002 |
Snowboard boot with removable forward support
Abstract
A snowboard boot (200) includes an upper boot (204) secured to
an outsole (206). The boot upper includes a vamp opening (208) that
is closed by a tongue (210) and a selectively securable vamp
fastener (216). The tongue (210) carries a pocket (218) on a lower
end (212) thereof, and first and second snap fasteners (222) on an
upper end (214) thereof. A semi-rigid tongue stiffener (202) can be
selectively secured to an anterior side of the tongue (210)
utilizing the pocket and snap fasteners to selectively increase the
stiffness of the boot and resistance to forward flexure by a
predetermined degree.
Inventors: |
Hall, William B.; (Seattle,
WA) ; Martin, John D.; (Vashon, WA) |
Correspondence
Address: |
CHRISTENSEN, O'CONNOR, JOHNSON, KINDNESS, PLLC
1420 FIFTH AVENUE
SUITE 2800
SEATTLE
WA
98101-2347
US
|
Family ID: |
25074721 |
Appl. No.: |
09/765867 |
Filed: |
January 19, 2001 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
09765867 |
Jan 19, 2001 |
|
|
|
09760326 |
Jan 12, 2001 |
|
|
|
Current U.S.
Class: |
36/117.1 ;
36/119.1; 36/54; 36/88 |
Current CPC
Class: |
A43B 5/0439 20130101;
A43B 19/00 20130101; A43D 999/00 20130101; A43B 5/0415 20130101;
A43B 5/049 20130101; A43B 3/0031 20130101; A43B 23/26 20130101;
A43B 7/20 20130101; A43B 5/0401 20130101 |
Class at
Publication: |
36/117.1 ; 36/54;
36/88; 36/119.1 |
International
Class: |
A43B 005/04; A43B
005/16 |
Claims
The embodiments of the invention in which an exclusive property or
privilege is claimed are defined as follows:
1. A snowboard boot comprising: an upper portion for receiving the
foot and ankle of a snowboarder, the upper portion including an
elongate vamp opening along the instep and anterior ankle of the
snowboarder, the upper portion being configured to permit forward
flexure of the snowboarder's ankle; a tongue secured to the upper
portion and positionable to cover the vamp opening; an outsole
joined to the upper portion; a vamp fastener carried on the upper
portion for selective closure of the vamp opening; and a semi-rigid
support insert having an upper end and a lower end, that is
selectively securable at the upper and lower ends thereof to a
surface of the tongue to selectively decrease the forward ankle
flexibility of the upper portion.
2. The snowboard boot of claim 1, wherein the semi-rigid support
insert when secured to the tongue extends from a lower end of the
instep to above the ankle of the snowboarder.
3. The snowboard boot of claim 1, wherein at least one end of the
support insert is secured to the tongue by being received within a
pocket defined on the tongue.
4. The snowboard boot of claim 3, wherein an opposite end of the
support insert is secured to the tongue by at least one snap
fastener carried on the tongue.
5. The snowboard boot of claim 1, wherein the support insert is
secured to the tongue by engaging a snap fastener carried on the
tongue.
6. The snowboard boot of claim 5, further comprising a plurality of
snap fasteners carried on the tongue to secure the support insert
thereto.
7. The snowboard boot of claim 1, further comprising a plurality of
semi-rigid support inserts, each having a differing predetermined
degree of flexibility to permit selective adjustment of the forward
flexibility of the snowboard boot.
8. The snowboard boot of claim 1, wherein the semi-rigid support
insert is formed as a curvilinear shape defining an overall "Y"
profile.
9. The snowboard boot of claim 1, wherein the semi-rigid support
insert is wider at the upper end than at the lower end.
10. The snowboard boot of claim 9, wherein the support insert
defines a center section that has a width that is narrower than a
width of the upper end and of the lower end.
11. The snowboard boot of claim 1, wherein the semi-rigid support
insert is secured to an anterior side of the tongue.
12. The snowboard boot of claim 11, wherein a recess is defined in
the anterior side of the tongue that receives the semi-rigid
support insert once the semi-rigid support insert is secured to the
tongue.
13. The snowboard boot of claim 1, wherein when secured to the
tongue, the semi-rigid support insert is disposed between the
tongue and the vamp fastener.
14. The snowboard boot of claim 1, wherein the tongue is secured to
the upper portion at a lower end of the tongue and is separate from
the upper portion along at least a first side of the tongue.
15. A snowboard boot comprising: an upper portion for receiving the
foot and ankle of a snowboarder, including an anterior ankle
portion covering the anterior of the ankle of the snowboarder and
an instep portion covering the instep of the snowboarder, and
including an access aperture for insertion of the snowboarder's
foot into the upper portion; an outsole joined to the upper
portion; a fastener for selective closure of the access opening of
the upper portion to tighten the upper portion about the
snowboarder's foot; and a semi-rigid support insert having an upper
end and a lower end, the semi-rigid support insert being
selectively securable to the upper portion adjacent the anterior
ankle portion and instep portion of the upper portion and securable
at the upper and lower ends thereof to the upper portion to
decrease the forward ankle flexibility of the upper portion.
16. A snowboard boot comprising: an upper portion for receiving the
foot and ankle of a snowboarder, the upper portion including an
elongate vamp opening along the instep and anterior ankle of the
snowboarder, the upper portion being configured to permit forward
flexure of the snowboarder's ankle; a tongue secured to the upper
portion and positionable to cover the vamp opening; an outsole
joined to the upper portion; a vamp fastener carried on the upper
portion for selective closure of the vamp opening; and a semi-rigid
support insert having an elongate body and an upper end, the
semi-rigid support insert being selectively securable at an upper
end to the tongue, overlying a surface of the tongue to selectively
decrease the forward ankle flexibility of the upper portion.
Description
TECHNICAL FIELD OF THE INVENTION
[0001] The present application is a continuation in part of U.S.
patent application Ser. No. [to be supplied] filed Jan. 12, 2001 in
the name of inventors Richard H. Oetting and John D. Martin,
entitled SNOWBOARD BOOT WITH REMOVABLE UPPER SUPPORT.
FIELD OF THE INVENTION
[0002] The present invention relates to snowboard boots, and more
particularly to snowboard boots having a flexible upper.
BACKGROUND OF THE INVENTION
[0003] Snowboarding is a popular winter sport in which a
snowboarder stands atop a snowboard and maneuvers the board over
the snow, propelled by gravity. The snowboarder wears boots that
are removably attached to the board, with the snowboarder's feet
angled with respect to the longitudinal axis of the board, and in
some cases, perpendicular to the board axis. The snowboard is
controlled by weight transfer and foot movement, both lateral and
longitudinal.
[0004] A primary skill that must be mastered in snowboarding is the
ability to carve a path through the snow, rather than simply
sliding over the top of the snow. Carving allows the snowboarder to
control the direction and speed of the snowboard. In its simplest
execution, a snowboarder carves a path through the snow by shifting
his or her weight forward or backward, causing the snowboard to
tilt or rotate about its longitudinal axis toward and away from its
back side edge. As used herein, frontside refers to the side or
direction to which the snowboarder's toes are closest and back side
refers to the opposite side or direction.
[0005] Snowboard boots are conventionally secured to the board
using either strap bindings or step-in bindings. In either case,
the binding and/or boot usually employs a high back structure that
extends upwardly from either the board or the back side of the boot
sole, along and behind the ankle of the boot. The high back limits
rearward flexure of the ankle so that when the snowboarder leans
backwards, force is transmitted to the snowboard tending to rotate
the snowboard about its longitudinal axis toward the back side
edge. The high back is secured to the board in conventional strap
bindings and in high back step-in bindings.
[0006] An alternative type of step-in binding is also available,
called a plate or flat step-in binding. Flat step-in bindings
utilize metal cleats on the bottom of the snowboard boot that mate
with a binding structure built into the snowboard, to secure the
snowboard boot to the snowboard. For example, two metal cleats are
sometimes provided on the bottom of each boot, one toward the front
portion of the boot and the other toward the heel of the boot.
Step-in bindings provide many advantages over strap and high back
step-in bindings, including ease of attachment and disattachment.
The flat step-in binding itself, however, does not provide a
connection between the snowboarder's calf and the frontside of the
snowboard. Therefore, in order to facilitate back side turns,
snowboard boots for use with flat step-in bindings are typically
much stiffer, particularly along the vertical back portion of the
upper, than are snowboard boots for strap and high back step-in
bindings. The functional equivalent of the high back is essentially
built into the snowboard boot for flat step-in bindings, rigidizing
the rear spine of the boot against rear flexion.
[0007] The choice of binding type and boot will depend on a variety
of factors. For example, in alpine snowboarding, wherein the
snowboarder typically maneuvers from the top to the bottom of a
snow-covered slope, it is generally preferred to have a stiffer
connection between the snowboarder and the snowboard. In free style
snowboarding, which typically involves performing more elaborate
tricks, more mobility and flexibility between the snowboarder and
the snowboard is desirable. Two or more different pairs of
snowboard boots may therefore be necessary for a snowboarder who
wants to do both alpine and free style snowboarding: One pair of
boots for use with strap or high back step-in bindings, another
pair of boots for flat step-in bindings, and possibly a third pair
of boots for use with flat step-in bindings that has a greater
degree of flexibility in the ankle portion.
[0008] In U.S. Pat. No. 5,966,843 to Sand et al., a boot structure
is disclosed for use with step-in bindings including an underfoot
or shank portion that connects to a heel cup and high back portion.
Straps are provided from the high back portion to the shank,
whereby backward motion of the high back portion will cause the
shank to rise. This boot essentially combines the features of a
high back binding and a step-in binding into a soft boot
structure.
[0009] A similar stiffening assembly is disclosed in U.S. Pat. No.
5,771,609 to Messmer, which teaches a boot insert including a rigid
underfoot portion pivotally attached to a rigid back plate, and a
pair of flexible tension straps extending between the back plate
and the underfoot portion. Neither Messmer nor Sand et al. teaches
a stiffening apparatus that can be removed from the boot.
[0010] In U.S. Pat. No. 5,606,808, Gilliard et al. teaches a
snowboard boot having at least one elongate exterior pocket in the
flexible upper portion of the boot with an open top channel to
receive a substantially uniform rectilinear cross-sectional
elongate stay, for stiffening the upper portion of the boot. The
stay, which is maintained in the pocket by frictional forces,
includes a strap for inserting and removing the stay, whereby the
snowboarder can adjust the stiffness of the boot upper portion. The
elongate stay does not, however, conform to the shape of the
snowboarders ankle, and is susceptible to being inadvertently
pulled out during use, for example if the snowboarder tumbles in
the snow or brushes against obstacles on the slope.
[0011] In addition to having need for differing levels of support
in the rear of a snowboard boot, there are different snowboarding
styles and activities which are facilitated by having a boot with
differing levels of stiffness on the anterior side of the ankle, to
revise the ease of forward flexure. For example, a snowboarder that
rides in a freestyle fashion, particularly in terrain such as a
half pipe or smaller jumps, typically prefers a relatively loose
boot with little limitation on forward flexure. Force transmission
from the user's lower leg to the toe edge of the board can be
finely tuned with a responsive feel, yet requires a high degree of
strength for accurate control. In contrast, a snowboarder that
rides an all mountain board, particularly at fast speeds, or that
tackles very large jumps, typically prefers a boot with a higher
degree of stiffness in the forward direction. The wearer is more
readily able to maintain control of the toe edge, particularly at
high speed, and force may be more efficiently transmitted from the
user's lower leg to the toe edge.
SUMMARY OF THE INVENTION
[0012] The present invention provides a boot for snow sports having
a sole portion and an upper portion that cooperatively receive a
user's foot. The upper portion has a flexible high back portion
adapted to surround the user's ankle. The high back portion
includes a pocket that is adapted to receive a removable,
semi-rigid insert that is wide at a top end and narrow at a bottom
end. By installing or removing the insert in the pocket, the
rearward flexibility of the high back portion of the boot can be
selectively modified.
[0013] In a further aspect of the present invention, the insert is
generally Y-shaped, and the high back portion of the boot also
includes a pair of locking slots that are positioned to receive
opposite corners of the top end of the insert, such that the insert
can be removably locked in place in the pocket.
[0014] In an aspect of one embodiment of the present invention, the
snowboard boot further comprises a soft liner that is insertable
into the boot to improve the user's comfort.
[0015] In a further aspect of the present invention, a snowboard
boot is provided that has an adjustable degree of forward
flexibility. The boot includes an upper secured to a sole, with the
upper including a vamp opening over the user's instep and the
anterior side of the user's ankle. The boot further includes a
tongue extending upwardly from the upper to cover the vamp opening,
and a selective fastener such as a lace or strap that closes the
vamp opening over the tongue. The boot includes a semi-rigid tongue
stiffener insert that is selectively securable at upper and lower
ends to the tongue to achieve a predetermined degree of forward
ankle flexibility. The tongue stiffener can be removed altogether
from the boot to provide a substantially unlimited degree of
forward flexure, or it can be inserted into the boot to increase
the stiffness of the boot upper to limit forward flexure. In a
further aspect of the present invention, a plurality of tongue
stiffeners having differing degrees of semi-rigidity are provided,
and a stiffener can be selected and installed for a predetermined
degree of forward flexural resistance.
BRIEF DESCRIPTION OF THE DRAWINGS
[0016] The foregoing aspects and many of the attendant advantages
of this invention will become more readily appreciated as the same
become better understood by reference to the following detailed
description, when taken in conjunction with the accompanying
drawings, wherein:
[0017] FIG. 1 is a perspective, partially exploded view of a pair
of snowboard boots made in accordance with the present invention,
shown atop a snowboard.
[0018] FIG. 2 is a partially cutaway perspective view of the
snowboard boot shown in FIG. 1.
[0019] FIG. 3 is a further cutaway perspective view of the
snowboard boot shown in FIG. 1.
[0020] FIG. 4 is a perspective, view of the pocket assembly and
insert of the snowboard boot shown in FIG. 1.
[0021] FIG. 5 is a cross-sectional view along line 5-5 of FIG. 4,
showing the insert installed in the pocket.
[0022] FIG. 6 is a flat pattern view of the insert of the snowboard
boot shown in FIG. 1.
[0023] FIG. 7 illustrates an alternative embodiment of the
invention including a selectively removable tongue stiffener.
[0024] FIG. 8 provides a perspective view of the snowboard boot of
FIG. 7 with the tongue stiffener exploded from the boot.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
[0025] A snowboard boot made in accordance with a preferred
embodiment of the present invention is illustrated in FIG. 1, which
shows a perspective, partially exploded view of two snowboard boots
100 on a snowboard 90. Each snowboard boot 100 includes a sole
portion 110, and a boot upper 120 that is connected to, and extends
upwardly from, the sole portion 110. The boot upper 120 has a
lower, or toe portion 122 that, cooperatively with the sole portion
110, generally encloses a user's foot (not shown), and a high back
portion 124 that wraps around the user's ankle (also not shown). A
soft, compressible liner 140, smaller than the boot 100 and
generally conforming to the shape of the user's foot, is provided
between the snowboard boot 100 and the user's foot, to increase the
comfort of and more closely conform to the user. A strap 126 and/or
laces 128 may be used to secure the snowboard boot 100 tightly
about the user's foot and ankle. If step-in bindings are to be
used, the sole portion 110 will further include cleats (not shown)
or other engaging members on its bottom side that engage
corresponding plate bindings on the snowboard 90.
[0026] The disclosed invention is adapted for use with a "soft"
boot. A "soft" boot upper is typically formed of a flexible
material, for example, a pliable leather, a woven fabric material
such as polymeric canvas, polymeric sheet material or a layered
combination of such materials. Such flexible materials are selected
to provide a relatively comfortable fit to the user and to provide
a limited range of motion at the ankle joint. In particular the
high back portion 124 may be constructed from fabric, leather,
elastomers, or combinations of these materials, by way of
nonlimiting example. The flexible high back portion 124 of the
boot, and therefore, the user's ankle, can flex or rotate about a
transverse axis, with respect to the toe portion 122, and
therefore, the user's foot. The high back portion 124 permits fore
and aft, and lateral and medial, flexure. This flexure provides a
degree of mobility to the user's ankle joint, which is important in
some snowboarding maneuvers, particularly in free style
snowboarding. The soft boot is also typically more comfortable to
the user than a hard shell boot.
[0027] As discussed above, it is sometimes desirable to provide
stiffer support to the user's ankle and a more limited range of
motion at the ankle joint, particularly in the aft direction, for
example, to enable the user to more easily control axial rotation
of the snowboard. The desired stiffness in the boot 100 will depend
upon several factors, including the user's preference and skill
level, the type of binding used, and on the type of snowboarding in
which the user will be engaging.
[0028] As shown in FIGS. 1-3, the boot 100 includes a curvilinear
stiffening insert 150 that is removably insertable into the boot
upper 120, between the boot upper 120 and the liner 140. A pocket
130 is provided in the back interior of the boot upper 120, which
slidably receives the insert 150. The pocket 130 includes a back
panel 132 that is attached to, and conforms to, the boot upper 120,
and a smaller front panel 133 attached to the front of the back
panel 132 as discussed in more detail below. In the currently
preferred embodiment, the front and back panels 132, 133 are made
from a semi-rigid material, providing a predetermined degree of
stiffness to the boot upper 120, although a more flexible
pocket--for example, made from leather or a similarly pliable
material--is also possible and contemplated by this invention. The
back panel 132 is preferably attached to the boot upper 120 with an
epoxy, although other attachment methods are possible and known in
the art, including sewing or riveting the back panel to the upper,
providing a frame that holds the back panel in place, or having the
back panel formed integrally with the boot upper material.
[0029] The back panel 132 has a curvilinear profile that generally
matches the desired shape of the portion of the boot upper 120 to
which it is attached. It will be appreciated that the back panel
132 therefore provides the additional benefit of tending to hold
the boot upper 120 in the desired shape. In the preferred
embodiment illustrated, the back panel 132 also includes a lower
portion that has a pair of elongate lower wings 135 extending
forward from bottom edge of the back panel 132 and generally
adjacent to the upper surface of the sole portion 110. The lower
wings 135 cooperatively with the back portion of the sole 110
therefore form a heel cup. The lower wings 135 provide the boot 100
and the user with additional support, by generally surrounding the
user's heel. Similarly, the top of the back panel 132 includes a
pair of upper wings 125 that extends forwardly from the top edge of
the back panel 132. The upper wings 125 wrap partially around the
user's ankle, whereby the back panel 132 provides lateral or
side-to-side stability to the boot upper 120 as well as forward and
backward stability.
[0030] The front panel 133 is smaller than the back panel 132 and
is attached to the front face of the back panel 132. In the
disclosed embodiment, the front panel 133 is also semi-rigid and is
sewn to the back panel 132 generally along both sides and at the
bottom edge of the front panel 133. As seen most clearly in FIG. 5,
the front panel 133 is shaped such that when the front panel 133 is
attached to the back panel 132, the central portion of the front
panel 133 is disposed forward from the back panel 132, thereby
forming a pocket 130 therebetween that is open at the top. In the
disclosed embodiment the pocket 130 is formed by forwardly
extending sections 145 near the side edges of the front panel 133.
It will be apparent to one of skill in the art that a pocket could
also be formed in other ways, including by providing the front
panel 133 with a radius of curvature that is greater than the
radius of curvature of the back panel 132. Alternatively, the front
panel 133 can simply be formed with sufficient flexibility that it
can be pulled away from the back panel 132 for insertion of the
insert 150. It will also be apparent that other configurations are
possible, for example the pocket opening could be provided on the
left or right side, and an insert provided that will slide sideways
into a side pocket.
[0031] The front panel 133 is widest at the open top, and decreases
uniformly in width from the top to the bottom. In the currently
preferred embodiment, the front panel 133 is attached to the back
panel 132 with stitches 142, generally conforming to the shape of
the front panel 133, although other attachment methods could also
be used. The pocket 130 is therefore open at the top, and decreases
uniformly in width from the top to the bottom.
[0032] Two locking strips 134 are attached at the top portion of
the upper wings 125 of the back panel 132, as seen most clearly in
FIG. 4. The locking strips 134 are attached generally along the
upper and side edges by stitches 144, thereby forming small,
downwardly-opening pockets or locking slots 131 on each side of the
upper edge of the back panel 132. It will be apparent to one of
skill in the art that equivalent locking slots could be provided in
other ways. For example, slots could be integrally formed in the
back panel by cutting slits at appropriate locations and forming a
portion of the back panel above the slot to project outwardly from
the face of the back panel. Alternatively, the back panel could be
formed with a portion that folds over to form a locking slot. The
locking slots 131 function to receive and retain the removable
stiffening insert 150 in place, as discussed below.
[0033] A curvilinear, generally Y-shaped insert 150 can be
removably inserted into the pocket 130, as shown in FIG. 4. The
insert 150 has a narrow lower tongue 152 extending downwardly, and
increases uniformly in width from the bottom of the tongue 152 to
the top, where a pair of elongate sections, or locking tabs 154,
extend upwardly and outwardly. FIG. 5 shows a cross sectional view
of the insert 150 inserted into the pocket 130 (taken along line
5-5 of FIG. 4). The insert 150 is smaller than, and generally
matches the shape of, the pocket 130, whereby the insert tongue 152
substantially fills the pocket 130. As seen most clearly in FIG. 3,
the insert 150 is longer than the pocket 130, so when the insert
150 is fully inserted into the pocket 130, the top portion of the
insert 150, including the pair of locking tabs 154, extends out of
the top of the pocket 130.
[0034] The insert 150 is sized and shaped such that when the insert
150 is fully inserted into the pocket 130, the locking tabs 154
overlie the locking slots 131. The insert 150 and the back panel
132 have sufficient flexibility that they can be elastically
deformed to allow the locking tabs 154 to be inserted into the
locking slots 131, thereby locking the insert 150 in the pocket
130, and securing the insert 150 against the back of the upper 120.
To lock the insert 150 into the slots 131, for example, a back
panel 132 upper wing 125 is grasped (with the associated section of
the upper high back portion 124) and rotated back and outward, with
respect to the rest of the boot 100. The corresponding locking tab
154 of the insert 150 is grasped with the other hand and deflected
back and inwardly, until the locking tab 154 slidably engages the
locking slot 131. The process is then repeated on the other
side.
[0035] Similarly, the back panel 132 and insert 150 can be
elastically deformed to remove the locking tabs 154 from the slots
131, by repeating the steps described above and slidably
disengaging the locking tabs 154 from the slots 131. It will be
appreciated that the insert 150 is curved in the transverse plane,
such that the insert generally matches the contours of the back
panel 132 and the front panel 133. Therefore, the upper portion of
the insert 150 and particularly the locking tabs 154 will partially
wrap around the user's leg, just above the ankle. The insert 150
will therefore provide additional rigidity or stability in the
lateral direction, that is, side to side with respect to the user,
as well as forward and backward stability. It will be appreciated
that the locking tabs 154 could be attached to the back panel 132
in other ways, for example, by providing snaps on the locking tabs
154 and the back panel 132, or using loop and hook-type
fasteners.
[0036] In the disclosed embodiment, generally vertically and
transversely extending ribs 156 are provided on the insert 150, to
increase the rigidity of the insert 150. As seen most clearly in
FIG. 5, the ribs 156 also reduce the area of the insert 150 that
contacts the interior of the pocket 130, thereby reducing the
frictional forces during insertion and removal of the insert 150.
FIG. 6 is a flat-pattern view of the insert 150, showing the
general Y-shape of the insert. The ribs 156 generally follow the
edge contour of the insert 150.
[0037] The insert 150 may be formed of any suitably semi-rigid
material having sufficient strength and shape stability, including
by way of non-limiting example, a semi-rigid nylon.TM. polymer, or
a carbon fiber reinforced composite. The desired combination of
rigidity and flexibility can be further selectably achieved by
modifying the geometry of the insert, for example the thickness of
the material or the number and/or size of surface features such as
ribs 156. Although in the preferred embodiment the back panel 132
and front panel 133 are made from a similar semi-rigid material, it
is also contemplated that the panels 132, 133 could be made from a
more flexible material, such as a woven fiber material or
leather.
[0038] A lining 137 covers the interior of the upper 120. The
lining includes a flap 136 that is attached to the top of the upper
120, and provides access to the pocket 130. A hook and loop type
fastener 138 is provided on the flap 136, that is alignable with a
matching hook and loop type fastener 139 on the body of the liner
137, to allow the flap 136 to be secured in a closed position,
whereby the liner 137 covers the back panel 132, front panel 133,
and insert 150.
[0039] It will be appreciated that the present invention allows the
user to selectively control the stiffness of the snowboard boots by
inserting or removing the insert 150 from the pocket 130. It is
contemplated that multiple inserts can be provided for a single
boot, the multiple inserts having differing stiffness
characteristics, whereby the user can selectively achieve varying
degrees of boot upper flexibility. In particular, a snowboard boot
made in accordance with the present invention could be used with
different types of bindings. If the snowboarder is using the boots
with a high back style binding, enhanced stiffness in the boot may
not be required because the binding attached to the snowboard will
provide the requisite board control. The insert 150 may be removed
for such cases. Even with a high back style binding, however, the
added lateral stability provided by the insert may be desirable.
Alternatively, if step-in plate bindings are to be used, where
greater boot stiffness is generally preferred, the snowboarder can
simply slide the insert 150 into the pocket 130. An additional
advantage of the present invention is that it would allow the
snowboarder to spread out the cost of upgrading to step-in bindings
over more than one season. If the snowboarder desired to switch to
step-in bindings, for example, he or she could purchase boots made
in accordance with the present invention in one season, and use
them with an existing strap binding, and then upgrade the snowboard
in a subsequent season.
[0040] Although the disclosed embodiment has been described having
an interior pocket, it is also contemplated by the present
invention that the pocket could be formed on the outside of the
snow boot upper such that an insert wrapping partially around the
snowboarder's ankle can be inserted into the pocket without
removing the boot. This alternative embodiment would have the
advantage that the interior of the boot would not have to
accommodate the insert and therefore a boot without a removable
liner 140 could be used.
[0041] Although the invention has been described with reference to
the preferred embodiment wherein a pocket is provided in the boot
to retain the insert, other means for retaining a rigid or
semi-rigid insert are also contemplated within the scope of the
present invention. For example and without limitation, it is
contemplated that a plurality of short retainer tabs could be
provide in the boot upper to retain an insert at three or more
attachment locations. Alternatively, a simple flexible flap at the
top of the upper, or an elastic strap, could be employed to retain
the insert cooperatively with the user's foot and/or the liner.
More positive locking mechanisms, such as snaps or hooks and hoops
type fasteners could also be attached to the boot upper and the
insert to lock the insert at the desired location within the
boot.
[0042] It should be readily apparent to those of ordinary skill in
the art that additional alterations could be made to the
above-described embodiment. For instance, the pocket for the insert
could be formed as a unitary pocket from a single piece of
material. Further, the insert could be formed with a strap, hoop,
or other grasping device to facilitate insertion and/or removal of
the insert from the boot. Also, a stacked, multipart insert could
be used wherein the stiffness of the upper can be adjusted by
changing the number of inserts that are inserted in the pocket.
Although the present invention has been described with reference to
snowboard boots, the application for which the invention was
developed, it is also contemplated that the invention will find
application in other sporting footwear in which varying degrees of
boot upper stiffness may be desired.
[0043] An alternative embodiment of a snowboard boot 200
constructed in accordance with another aspect of the invention is
shown in FIGS. 7 and 8. The snowboard boot 200 is similar to the
previously described snowboard boot 100, but rather than having a
selectively removable stiffener for control and limitation of aft
flexure, the snowboard boot 200 includes a selectively removable
tongue stiffener 202 to allow the boot to be adapted for differing
degrees of resistance to forward ankle flexure. Those aspects of
the snowboard boot 200 in common with the previously described
snowboard boot 100 will not be described again in detail to avoid
redundancy.
[0044] Briefly, the snowboard boot 200 includes a flexible upper
204 that is joined to an outsole 206. As in the previously
described embodiment, the flexible upper 204 is suitably formed
from fabric such as nylon, leather, or other flexible materials,
includes internal padding, and may also include an internal heel
and ankle support structure (not shown). Alternately, the boot may
not include an internal ankle support, instead relying on a
conventional external highback carried on a snowboard binding.
[0045] The boot upper 204 includes a vamp opening 208. The vamp
opening 208 is an elongate gap in the anterior side of the boot
upper 204, extending along the user's instep and anterior side of
the ankle. The vamp opening is covered by an elongate tongue 210.
The elongate tongue 210 has a lower end 212 and an upper end 214.
The lower end 212 of the tongue is stitched to the interior of the
boot upper 204 at the bottom, forwardmost end of the vamp opening
208. The tongue 210 extends upwardly along the interior of the vamp
opening 208, with the upper end 214 of the tongue 210 terminating
above the ankle of the user. The left and right longitudinal edges
of the tongue 210 are overlapped by the left and right sides of the
boot upper 204 alongside the vamp opening 208. As in a conventional
boot, the snowboard boot 200 also includes a selective vamp
closure, such as a lacing system 216 that optionally includes a
strap assembly 217 to fasten the vamp closure 208 and tighten it
over the tongue 210. The tongue 210 includes an outer flexible
layer and internal padding.
[0046] In the embodiment illustrated, the left and right edges of
the tongue 210 are not connected to the boot upper 204, with the
tongue 210 being connected only at the lower end to the boot upper
204. However, it should be readily apparent that the invention is
also suitably used with a boot that includes folds along the left
and right edges of the tongue that are stitched to the interior of
the boot upper 204. Additionally, the invention may be used with a
boot having no vamp opening, instead including a side or rear
access aperture.
[0047] The tongue stiffener 202, or other semi-rigid insert, can be
either installed on the tongue 210, as shown in FIG. 7, or
selectively removed from the tongue 210, as shown in FIG. 8. Once
so removed from the boot, the tongue 210 has an overall
conventional construction. However, the tongue 210 includes
mounting structures that provide for installation of the tongue
stiffener 202. Specifically, a pocket 218 is formed on the outer
surface of the lower end 212 of the tongue 210. The pocket 218 is
constructed from a flap of material, such as a semi-rigid plastic
sheet or a section of fabric, secured about its lower edge and
sides to the tongue, such as by stitching or by an adhesive.
Alternately, the flap 218 can be integrally formed as a portion of
one of the fabric or other material layers of the tongue. An
opening 220 exists on the upper side of the pocket 218, and in the
preferred embodiment illustrated, the opening 220 is recessed in
the center of the tongue.
[0048] The upper end 214 of the tongue includes first and second
snap fasteners 222. The snap fasteners are secured to the left and
right sides of the upper end 214 of the tongue 210, adjacent the
left and right sides of the vamp opening 208. The snap fasteners
222 each include an enlarged head 224 that projects radially
outward from a slightly smaller base 226. The base 226 is secured
to the upper end 214 of the tongue 210. In a preferred embodiment,
the base includes an annular flange that is received under an outer
layer of the tongue, and is stitched to the tongue, with the head
222 projecting from an aperture formed in the outer layer. This
anchors the snaps 222 in place so that they are non-removably
affixed to the tongue 210. The purpose of the pocket 218 and the
first and second snaps 222 is to allow for selective installation
of the tongue stiffener 202. However, when the tongue stiffener 202
is not in position, they do not limit or impact the function of the
boot 200, and in particular do not limit or provide any substantial
resistance to forward flexure of the ankle portion of the boot.
Thus when so removed, the boot freely flexes forwardly.
[0049] Referencing FIGS. 7 and 8, the tongue stiffener 202 has a
generally elongate "Y" shape configuration. The tongue stiffener
202 is formed from a compound curvilinear sheet. The tongue
stiffener 202 has a lower pointed end 230, a longitudinal center
body 232 that decreases in width at a centermost point, and an
upper end that bifurcates into left and right upper forks 234. The
left and right forks 234 of the upper end of the tongue stiffener
202 thus form the tops of the "Y". Overall, the tongue stiffener
202 is narrowest at its center point, which when the tongue
stiffener 202 is installed corresponds generally to the arcuate
joinder of the instep and anterior ankle surface of the user's
foot. In an unflexed configuration, the tongue stiffener 202 is
curved at this center point. Additionally, the entire tongue
stiffener is cured three dimensionally to match the contour of the
user's foot and ankle.
[0050] Just as for the previously described inserts 150, the tongue
stiffener 202 is suitably formed from a semi-rigid material having
a predetermined degree of strength, shape stability, and resilient
flexibility. Suitable materials include thermoplastic polymers such
as hytrel.TM. and nylon.TM. polyamides. In order to provide a
predetermined degree of resistance to forward flexure of the boot,
suitable materials having varying degrees of semi-rigidity, such as
a shore D hardness of 50 to 100 or higher or lower, may be
selected. Other suitable materials, such as spring steel, are also
within the scope of the present invention providing they have the
desired predetermined degree of flexibility.
[0051] To install the tongue stiffener 202, the vamp closure 216 is
opened, exposing the anterior face of the tongue 210. The lower end
230 of the tongue stiffener 202 is then inserted into the interior
of the pocket 218 on the tongue 210. An aperture 236 is formed
through the center of each upper fork 234 of the tongue stiffener
202. The apertures 236 align with the snap fasteners 222 when the
tongue stiffener 202 is installed in place over the interior face
of the tongue 210. The apertures 236 have a diameter slightly less
than the diameter of the heads 224 of the snap fasteners 222, and
the material from which the tongue stiffener 202 is formed has
sufficient resiliency to deform about the heads 224 when the tongue
stiffener 202 is pushed down to engage the snap fasteners 222
within the apertures 236.
[0052] As so installed, the tongue stiffener 202 is selectively
secured or anchored both at the upper end and at the lower end to
the tongue 202. The resilient tongue stiffener 202 provides
resistance to forward flexure of the ankle of the user of the
snowboard, increasing the stiffness of the boot upper 204 in the
forward direction. Because of the lateral and medial extensions of
the upper forks 234 of the stiffener 202, a predetermined degree of
lateral and medial stiffness is also imparted to the boot. Lateral
and medial flexure of the boot upper requires torsional deformation
of the tongue stiffener 202. A recess 238 is formed in the anterior
surface of the tongue 210, which generally conforms to the shape of
the tongue stiffener 202, so that the tongue stiffener 202 when
installed lies flush on the tongue and does not bulge out
forwardly, for aesthetics and better fit.
[0053] The degree of forward flexure resistance and torsional
rigidity provided by the tongue insert 202 may be varied, as noted
above, by selecting different materials for the tongue. Likewise,
the thickness of the tongue stiffener 202 may be varied to increase
or decrease stiffness, and the width of the tongue stiffener 202,
particularly at the center section 232, may also be varied to
change the stiffness and torsional stability. Further, grooves or
ribs may be formed in the tongue stiffener 202 to strengthen (in
the case of ribs) or increase the flexibility (in the case of
grooves) of the tongue stiffener 202.
[0054] In the preferred embodiment, the tongue 202 is anchored and
seated at both the forward and upper ends. Other mechanisms of
mounting the tongue stiffener 202 may be utilized. Thus rather than
snaps at the top and a pocket at the bottom, snaps may be included
at both upper and lower ends, or pockets at both upper and lower
ends. Greater or fewer snaps, such as four snaps (two top and two
bottom), or two snaps (one top and one bottom), or other fasteners
such as clips may be utilized. Further, the entire tongue stiffener
202 may be received within a full length pocket, with a closure
added as in the previously described boot 100 to anchor or seat the
tongue stiffener 202 in position. A user may be provided with a
selection of tongue stiffeners 202 of varying stiffnesses to allow
the user to "dial in" or finely tune the forward flexibility and
torsional stiffness of the boot for differing riding
conditions.
[0055] While the previously described tongue stiffener 202 is made
of a uniform material and thickness, different regions of the
tongue stiffener 202 may be varied to impact the performance of the
boot. Thus for example the left or right fork 234 of the tongue
stiffener 202 may be increased or decreased in thickness or
otherwise changed in shape so that the boot is able to flex more
medially than it is laterally, or vice versa. Thus, the stiffener
202 can be configured with portions of differing thickness or
stiffness to correct for a given torsional stability in the lateral
direction relative to the medial direction.
[0056] As compared to other boot stiffeners, the tongue stiffener
202 is retained securely in place during use, does not impact
normal tightening and loosening of the boot using the vamp
fastener, and does not increase the bulkiness of the boot. While
the tongue stiffener 202 has been described as being mounted on the
anterior surface of the tongue 210, the tongue stiffener 202 could
alternately be mounted on the posterior (interior) surface, or
within an interior pocket, of the tongue 210.
[0057] While the preferred embodiment of the invention has been
illustrated and described, it will be appreciated that various
changes can be made therein without departing from the spirit and
scope of the invention.
* * * * *