Shoe having an internal chassis

Information

  • Patent Grant
  • 6658766
  • Patent Number
    6,658,766
  • Date Filed
    Thursday, May 4, 2000
    24 years ago
  • Date Issued
    Tuesday, December 9, 2003
    21 years ago
Abstract
A structural chassis includes a structural chassis and a foam chassis or sock liner sandwiched together to form an assembly that can be inserted into and substantially occupy a footbed of a shoe upper. Discrete sole elements are attached to a bottom side of the upper so as to expose certain portions of the bottom side therebetween. This absence of outsole material in those areas makes the upper collapsible about those areas since the outsole provides no support in those areas. Instead, the structure is provided by the chassis of the chassis, which is customized to the user's foot by placing one or more notches in strategic locations along the chassis where the foot naturally flexes. One such notch is located on the chassis in a position that allows the chassis to flex about a forward push-off axis of the foot that runs through the first and second MTP joints. Two collinear notches are formed on the chassis to allow the structural chassis shoe to flex about a lateral push-off axis that runs through the third, fourth and fifth MTP joints.
Description




BACKGROUND OF THE INVENTION




This invention relates generally to shoes, and more particularly to shoes wherein light weight and the ability to tailor the stiffness and flexure of the shoe is an important consideration.




Shoes encounter tremendous forces during running or sports. Over the years, efforts have been made to reduce the resultant stresses on the feet and legs. Once advance in this area has been the incorporation of cushioning material in the shoe sole to absorb the impact and cushion the foot as the shoe strikes the ground. This cushioning material is typically formed into a layer called the “midsole” which is interposed between the ground-engaging “outsole” and the shoe upper. The cushioning midsole, which should also flex with the foot, is typically made of ethyl-vinyl-acetate (EVA) or polyurethane (PU), although other resilient, cushioning materials could be used.




While the cushioning provided by a midsole is an advantage, its added weight hinders the performance of athletic shoes (particularly running shoes), which must be as light as possible. The problem of added weight from the midsole is recognized in U.S. Pat. No. 5,319,866 issued to Foley et al. Foley et al. attempts to solve the problem by substituting an arch support in place of the midsole and outsole underlying the arch area of the foot.




The use of a midsole between the outsole and the upper also positions the foot higher above the ground, creating a less stable platform for the foot. This problem is addressed to some degree in U.S. Pat. No. 4,542,598 issued to Misevich et al. The Misevich shoe includes a heel plate between two heel midsole layers to support and cushion the heel, and a forefoot board inside the upper over a forefoot midsole layer to support and cushion the forefoot. As in Foley, Misevich eliminates the midsole beneath the arch, thereby saving some weight. Unlike Foley, however, Misevich does not provide any additional structure to support the arch.




The negative effects of the impact to the feet and legs can be amplified if the shoes are not properly shaped and tuned to the particular sport, and to the individual's foot. Mass-produced athletic shoes come in standard sizes and shapes, and usually include an arch support designed to fit a “standard” foot. Prior art shoes, such as those typified by Foley and Misevich, include no provision for tailoring the shoe to fit an individual foot, except for the use of orthotics. Orthotics are well-known in the art, and are exemplified by U.S. Pat. No. 4,803,747 issued to Brown. Orthotics, however useful, represent additional, undesirable weight, and also stiffen the shoe and otherwise compromise its performance.




A further disadvantage of the prior art shoes is that they cannot be readily “tuned” to meet the particular needs of the wearer. This is particularly important for athletes who demand maximum performance out of their shoes. What “tunability” is provided by the prior art requires a complex trade off between all of the elements of the shoe including the outsole, the midsole, and structural members that make-up the shoe, and must normally be done at the design stage, and cannot be varied by the customer.




Accordingly, a need remains for a light-weight shoe that minimizes the material in the sole, adequately supports the foot, and which can be readily customized for an individual's foot or for a particular activity.




SUMMARY OF THE INVENTION




It is, therefore, an object of the invention to provide a shoe, in particular an athletic shoe, which can be customized to support the foot according to an individual's specific characteristics and the requirements of a particular sport or activity.




It is another object of the invention to eliminate the need for an outsole and midsole which span substantially the entire length of the shoe.




It is still another object of the invention to provide a shoe having a removeable support member within the upper, and which can be selected to provide optimum support for the wearer's foot, and which can also be selected to optimize the support and flexure characteristics of the shoe for a particular activity.




It is yet another object of the invention to provide a shoe having a lacing system which does not irritate the tendons and connective tissue in the foot.




A shoe according to the invention includes an upper, a removeable chassis, or support member, within the upper to support the foot, and one or more ground-engaging sole elements affixed to the bottom of the upper at discrete locations, and which leave portions of the upper unsupported by the sole elements. The weight of the shoe is thereby minimized because the full-length midsole and outsole have been replaced by the discrete sole elements. The structural chassis may be contoured to closely fit the underside of the foot, and may include an overlayed foam insole or sock liner, which may also be contoured to fit the underside of the foot. In one embodiment, the structural chassis has one or more notches or slots in locations selected to permit a desired flexure of the foot. The length and width of the notches can be varied to vary the shoe's flexibility. Alternatively, the structural chassis can be without flexure notches, and rely instead on differing thicknesses of materials to vary its flexibility in different areas of the shoe.




Because the structural chassis can be readily removed and another installed in its place, the shoe can be custom fitted to an individual's foot, or optimized for a specific activity by substituting a different structural chassis.




In another aspect of the invention, a lace guide wraps under the shoe and upwardly around the sides about midway along the upper. The lace guide provides a plurality of beads through which a lace can be wrapped to secure the shoe to the user's foot. The lace guide is made of a flexible, translucent plastic in the preferred embodiment, and is sewn into the upper with the beads exposed. The lace guide also cooperates with the structural chassis by providing a recess that receives a corresponding protrusion in the structural chassis when it is inserted into the upper. The lace guide thereby aligns the structural chassis in the upper, and helps maintains it in position while in use.




A shoe according to the present invention utilizes a single structure for altering the support and flex of the shoe, thereby overcoming the disadvantage in the prior art that requires multiple elements to be modified to achieve the same result.




The foregoing and other objects, features and advantages of the invention will become more readily apparent from the following detailed description of a preferred embodiment of the invention which proceeds with reference to the accompanying drawings.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a right side elevational view of a shoe according to the invention.





FIG. 2

is a left side elevational view of the shoe shown in FIG.


1


.





FIG. 3

is a bottom plan view of the shoe shown in FIG.


1


.





FIG. 4

is a top plan view of a human foot skeleton.





FIG. 5

is a top plan view of a first embodiment of a structural chassis for use with the shoe of FIG.


1


.





FIG. 5A

is a cross sectional view of the structural chassis of

FIG. 5

taken along lines A—A.





FIG. 6

is a top plan view of a second embodiment of a structural chassis for use with a left shoe according to the invention.





FIG. 7

is an elevational view of the lateral side of the structural chassis of FIG.


6


.





FIG. 8

is an elevational view of the medial side of the structural chassis of FIG.


6


.





FIG. 9

is a bottom plan view of a structural chassis comprised of a third embodiment of a structural chassis and a foam chassis for use with the shoe of FIG.


1


.





FIG. 10

is a cross sectional view of the structural chassis of

FIG. 9

taken about lines


10





10


therein.





FIG. 11

is a cross sectional view of the shoe of

FIG. 1

with the chassis of

FIG. 9

taken along lines


11





11


in FIG.


3


.





FIG. 12

is a cross sectional view of the shoe of

FIG. 1

with the chassis of

FIG. 9

taken along lines


12





12


in FIG.


3


.





FIG. 13

is a bottom plan view of a first embodiment of a lace guide of the shoe shown in

FIG. 1

according to another aspect of the invention.





FIG. 13A

is a cross sectional view of the lace guide of

FIG. 13

taken-about lines A—A therein.





FIG. 13B

is a cross sectional view of the lace guide of

FIG. 13

taken about lines B—B therein.





FIG. 13C

is a cross sectional view of the lace guide of

FIG. 13

taken about lines C—C therein.





FIG. 13D

is a cross sectional view of the lace guide of

FIG. 13

taken about lines D—D therein.





FIG. 14

is a bottom plan view of a second embodiment of a lace guide of the shoe shown in FIG.


1


.





FIG. 15

is a bottom plan view of a second embodiment of a shoe according to the invention.





FIG. 16

is a perspective view of onf-embodiment of the invention in which sole elements are filled with a fluid or with a visco-elastic material.





FIG. 17

is a cross-sectional view of the embodiment shown in

FIG. 16

along line


17





17


.











DETAILED DESCRIPTION




A right shoe


10


according to the invention is shown in

FIGS. 1-3

. A corresponding left shoe is a mirror image of the right shoe and is therefore not described further. The shoe includes an upper


12


that is designed to receive a foot. The upper


12


can be made of any number of materials as is known in the art including mesh and/or leather. Affixed to the upper


12


is an exposed mesh tongue


14


. In the embodiment shown in

FIGS. 1 and 3

, the shoe uses a lace guide which will be described in greater detail below. In alternate embodiments (not shown) a conventional lacing system incorporating holes in the upper is used. The upper further includes a foam-filled ankle collar


16


surrounding the ankle opening of the shoe for added comfort. The description of the upper


12


is by way of illustration, and not for purposes of limitation, since numerous alternative uppers will work in combination with the structural chassis described further below.




The embodiment shown in

FIGS. 1-3

includes three distinct sole elements


18


,


20


and


22


, as shown most clearly in the bottom plan view of FIG.


3


. The invention is not limited to a particular number or configuration of sole elements. As will be appreciated by persons skilled in the art, more or fewer sole elements of different configurations may be used. Sole elements may be positioned to correspond to one or more ground-engaging anatomical structures of the unshod foot. Referring to

FIG. 4

, these points include, but are-not limited to, the calcaneus, the head of the first metatarsal, the head of the fifth metatarsal, the base of the fifth metatarsal, the head of the first distal phalange, and the head of the fifth distal phalange.




Each sole element provides traction, abrasion resistance and cushioning. These functions can be satisfied in many different ways. Referring to

FIG. 11

for example, sole element


18


has an outer, abrasion-resistant layer made from a material such as a durable rubber. The outer layer


19


encases a cushioning material


96


such as EVA or PU. In the embodiment shown in

FIGS. 1-3

, sole elements


20


and


22


also include an outer abrasion-resistant layer encasing a cushioning material. Other embodiments of the sole elements are described further below. Each sole element is affixed to the bottom of the upper using conventional techniques such as gluing and/or stitching. Sole element


18


is affixed to the heel portion of the upper where it provides traction, and cushions impacts to the calcaneus or heel bone of the foot. Element


20


is affixed to the upper in the region underlying the “ball of the foot”, and provides traction and cushioning for three critical load-bearing points on the foot: the first metatarsal head, the fifth metatarsal head, and the base of the fifth metatarsal in the lateral midtarsal portion of the foot. Sole element


22


is affixed to the upper below the toe region of the upper, and extends forward and upwardly around the front end of the upper


12


. Any number of different surface ornamentations can be applied to these portions, limited only by the creativity and ingenuity of the shoe designer.




The sole elements


18


,


20


and


22


in the preferred embodiment include rounded edges as shown at


18


S in FIG.


11


and at


20


S in

FIG. 12

, which extend upwardly around the medial and lateral sides of the sole, and follow the natural contour of the foot so as to provide maximum lateral stability. This is in contrast to the abrupt edges of the prior art, which can cause excessive ankle strain due to a lever arm effect, which is explained in greater detail in U.S. Pat. No. 5,317,819 to Ellis, the teachings of which are hereby incorporated by reference.




In another embodiment, the sole elements are filled with gas, such as air, or a visco-elastic material. A yet further embodiment of the sole elements is shown in

FIGS. 16 and 17

. In those figures an individual sole element


160


is shown, which is preferably mounted on the-shoe underneath the calcaneus bone, i.e., the heel. As in the embodiment described earlier, other similar sole elements can be placed in other load bearing points on the shoe corresponding to one or more ground-engaging anatomical structures of the unshod foot, including, but not limited to the calcaneus, the head of the first metatarsal, the head of the fifth metatarsal, the base of the fifth metatarsal, the head of the first distal phalange, and the head of the fifth distal phalange.




Sole element


160


includes a plurality of air or visco-elastic filled deformation elements


162


,


164


,


166


and


168


. These deformation elements are mounted on a base layer


170


. The deformation elements are preferably elongate, channels extending generally, radially outward from a common origin


176


. The channels are formed by sidewalls


172


extending vertically upward from the base layer to a top, ground-contacting surface


174


and sealed by end-walls to form sealed interior channels


178


. These channels


178


are then filled with a gas, such as air, or a visco-elastic material. A plurality of hollow, intermediate ribs


180


can be mounted on the base plate between adjacent deformation elements. The deformation elements allow the base plate to shift horizontally relative to the ground-contacting surface as a result of impact. This shifting reduces the impact by increasing the amount of time the load is dissipated over. Other embodiments of these deformation elements are described in commonly-assigned, copending patent application Ser. No. 08/327,461 filed Aug. 16, 1995 entitled “Anisotropic Deformation pad for Footwear,” incorporated herein by reference. The shoe according to the invention can work with any of the embodiments shown therein.




As can be seen in

FIG. 3

, the sole is not a contiguous outsole, but instead has one or more gaps between the sole elements, which expose the bottom side of the upper. In the preferred embodiment, two gaps are created by the design and placement of the sole elements, but the invention is not limited thereto. First medial gap


24


extends between the heel sole element and the forefoot sole element. This medial gap in general underlies the arch of the foot and extends across the entire width thereof. In the absence of any further structural support, the shoe is collapsible about this medial gap since the upper lacks much structural support. An X-shaped gap, referred to as a flex groove portion


26


, is defined between the forefoot portion


20


and the toe portion


22


. The flex groove portion


26


exposes a similarly shaped portion of the upper about which the shoe flexes. Axes F


1


and F


2


correspond generally to the natural forward and lateral “push-off” flexure axes, which are defined by the metatarsal phalangeal (MTP) joints, and which are described further below. In the preferred embodiment, axes F


1


and F


2


are set back about 10-15 mm from, and are parallel to, the respective forward and lateral push-off axes.




Structural support for the foot is provided by a structural chassis according to the invention. The design of the structural chassis is based on the structure and bio-mechanics of the human foot. A top plan view of a right human foot skeleton is shown in FIG.


4


. The foot is-attached to the leg (not shown) by the talus or anklebone


28


. Positioned below and rearwardly of the talus


28


is the calcaneus


30


(i.e., the heel bone). The navicular


32


and the cuboid


34


are positioned below and forward of the talus


28


. Three cuneiform bones


36


(labeled 1, 2 and 3) extend forwardly from the navicular


32


. Extending forwardly from the cuneiform bones


36


and from the cuboid


34


are the five metatarsals


38


, which are numbered 1 through 5 from left to right in

FIG. 4

(i.e., from big toe to little toe). Forwardly of each metatarsal bone is a respective phalange


40


that forms the toe.




Between each metatarsal and its respective phalange is a metatarsal phalangeal (MTP) joint. Thus, there are five MTP joints in all: a first MTP joint


42


, a second MTP joint


44


, a third MTP joint


46


, a fourth MTP joint


48


, and a fifth MTP joint


50


. These MTP joints can be used to define two axes about which the foot pushes off during certain push-off movements. A first axis A


1


is formed by a line generally through the first and second MTP joints


42


and


44


, respectively. This first axis is used for push-off while running straight ahead and is thus referred to as the forward push-off axis. The forward push-off axis is located at approximately 69% of the distance L from heel to toe. The forward push-off axis is generally perpendicular to a longitudinal axis Y running through a midpoint of the talus


28


and the first MTP joint


42


.




A lateral push-off axis A


2


is defined by a line running generally through the third (


46


), fourth (


48


), and fifth (


50


) MTP joints. The lateral push-off axis is used for push-offs towards the lateral side. The lateral push-off axis A


2


intersects the forward push-off axis A


1


, at an acute angle Ø. The distance from the rear of the calcaneus bone to the intersection of lateral push-off axis and the fifth MTP joint is approximately 62% of length L.




Turning now to

FIG. 5

, structural chassis


52


is designed to accommodate the natural flexing of the foot about the above-defined push-off axes. In general, chassis


52


supports the foot along its entire length, and at the same time accommodates the foot's natural flexion. Chassis


52


is generally shaped in plan view to match the outline of the foot, and extends the entire length thereof. Chassis


52


is preferably made of a relatively stiff, resilient material, such as vinyl or plastic, and provides the structural support for the shoe in those areas without any outsole or midsole material. The chassis can be custom-made to fit the user's foot as well as customized according to the requirements of the user's body and the shoe's intended application. The chassis


52


is inserted into the upper along with a foam insole or sock liner (not shown) which is interposed between the user's foot and the chassis. A combined chassis and foam insert assembly is shown and described hereinafter with reference to

FIGS. 9 and 10

.




The chassis


52


includes an arch support flange


54


that underlies the arch of the foot and provides structural support therefor. The size and shape of the flange


54


can be modified according to the amount of support required. Two notches


56


and


58


are cut into the chassis at the base of the flange to allow the chassis to twist about its longitudinal axis. The length and/or width of these notches


56


and


58


determines the torsional flexibility of the chassis about its longitudinal axis.




Adjacent the arch support flange


54


is a downwardly projecting protrusion


60


which serves to align and retain the chassis in place within the shoe. Since the chassis extends the full length of the footbed, however, the protrusion


60


is not essential to the operation of the chassis since the chassis will remain substantially in place in any case.




A transverse notch


62


is formed in the forefoot portion of the chassis and determines the flexibility of the chassis (and therefore the shoe) along axis A


1


′. The notch


62


is formed along a forward axis A


1


′ that is designed to generally underlie the forward push-off axis of the foot (A


1


). Axis A


1


′ is positioned approximately 10-15 mm forward of and parallel to axis F


1


when the chassis is inserted into the shoe. The length and width of notch


62


can be selected to provide a desired degree of stiffness and/or flexibility along line A


1


.




Notches


64


and


66


are formed on opposite sides of the chassis along axis A


2


. Axis A


2


′ underlays the lateral push-off axis (A


2


) of the foot. Axis A


2


′, as with axis A


1


′, is positioned forward of (by approximately 10-15 mm) and parallel to axis F


2


of the flex groove portion


26


. This separation ensures that the ground-engaging portion of the sole element remains in contact with the ground as the shoe flexes. As with notch


62


, the length and/or width of these two notches can be adapted individually to produce the desired stiffness and/or flexibility of the shoe about the lateral axis A


2


′. The forward and lateral axes A


1


′ and A


2


′ intersect one another at an angle Ø′, which corresponds generally to the angle of intersection of the forward and lateral push-off axes of the foot shown and described above. In the preferred embodiment of the invention, the angles Ø and Ø′ are 37 degrees, although other angles could be selected.




Chassis


52


may further include three notches


68


in the toe portion that permit the shoe to flex in that area. Each notch


68


begins at a point on the outer perimeter of the chassis between two adjacent toes allowing the chassis to flex individually in between the toes. The length and/or width of these notches can be adjusted to adapt the flexibility of the chassis (and therefore, the shoe) about the toe portion according to the requirements of the user.




Two arcuate slots


70


and


72


are formed in the heel portion of the chassis to provide flexibility in this region. Additional slots can be formed within these two slots


70


and


72


if additional flexibility is required in this region and, as with the other notches described above, the length and/or width can be modified.




A second embodiment of a structural chassis for a left foot is shown in

FIGS. 6-8

. The chassis


152


shown therein is similar to that shown in

FIG. 5

, and common elements retain common reference numerals. There are, however, several differences between the two chassis. The first is that the lateral edge portion S


L


along the lateral side of the chassis


152


is straight. Another is that a toe portion of chassis


152


is offset by an angle relative to a longitudinal axis Y


1


bisecting the midfoot and heel portions of the chassis. This angle is approximately 10-20 degrees in the preferred embodiment. Yet another difference is that the axis running through the slot


62


is approximately perpendicular to the longitudinal axis Y


1


. The angle Ø, however, remains the same as in chassis


52


. The arch support flange


54


and heel portion


153


of the chassis


152


are also reinforced to provide additional structural support relative to the rest of the chassis. In the preferred embodiment of this chassis, arch support flange


54


and heel portion


153


have a thickness of approximately 3 mm while the remainder of the chassis is approximately 2.5 mm.




Referring now to

FIG. 9

, a bottom plan view of a third embodiment of the invention, shown at


74


, comprises a chassis


76


integrally bonded to a foam insert or sock liner


78


. The sock liner


78


forms the outer perimeter of the chassis since the chassis


76


has a slightly smaller footprint. Thus a small space exists between the sock liner


78


and the chassis


76


around the perimeter of insert


74


, as shown in FIG.


9


.




Chassis


76


includes a slot


80


which is offset relative to the forward push-off axis of the foot (not shown) by an acute angle. Opposing tear-shaped notches


82


and


84


are also included on chassis


76


, to allow the chassis to flex about a lateral axis formed therethrough. Chassis


152


further includes a protrusion or bubble


86


that aligns the chassis in the upper, as well as an arch support flange


88


extending upwardly away therefrom. Opposed notches


90


and


92


adjacent flange


88


provide flexibility about longitudinal axis Y′. A slight depression


94


forms a downwardly deflectable portion in the heel portion of chassis


152


.





FIG. 10

, a cross sectional view of chassis


152


taken about line


10





10


in

FIG. 9

, shows that the chassis and the foam inlay or sock liner are contoured to the underside of the foot. The exception to this is the protrusion


86


on the chassis that extends downwardly away from the foam inlay and which is occupied thereby. As will be described further below, this protrusion or bubble


86


fits within a hole formed in the bottom side of the upper to align the chassis within the footbed of the shoe and keep the chassis from slipping. The bubble, however, is not essential to the main object of the invention.




Two cross sectional views of the assembled shoe shown in

FIGS. 1-3

are shown in

FIGS. 11-12

. The cross sectional view shown in

FIG. 11

is taken about lines


11





11


in

FIG. 3

while that shown in

FIG. 12

is taken about lines


12





12


therein. Referring now to

FIG. 11

, chassis


76


is shown in the footbed of upper


12


, and overlaid by the foam insole or sock liner


78


is placed in direct contact with the foot while the structural chassis


76


is interposed between the foam inlay or sock liner


78


and the upper


12


. Affixed to the bottom side of the upper is the heel sole element


18


is filled with a cushioning midsole material


96


such as ethyl vinyl acetate (EVA).




Referring now to FIGS.


3


and


12


-


13


, a lace guide


98


is generally shown. Lace guide


98


is a flexible plastic piece that is sewn into the upper through which a shoe lace is guided to secure the shoe to the foot. The lace guide includes a bubble


100


that forms a receptacle that receives the protrusion


86


of the structural chassis. In the preferred embodiment, the outer surface of protrusion


86


is placed in an abutting relationship with an inner surface of the bubble


100


. Although the bubble


100


shown and described herein is oval in shape, it is not limited thereto. Rather, any shape that acts to align the structural chassis in the footbed can be used so long as it is shaped to be received therein. In addition, also affixed to the bottom side of the upper is sole element


20


which is filled with a cushioning material


102


, such as EVA or PU.




A plan view of lace guide


98


is shown in FIG.


13


. Lace guide


98


wraps around the underside of the shoe and extends up along both sides. Bubble


100


is received in an opening


116


in upper


12


(

FIG. 3

) to align the lace guide with the upper. In one embodiment, lace guide


98


is made of a translucent material so that the chassis is visible through the bubble on the underside of the shoe. The lace guide is made of a flexible, lightweight material so that the lace guide does not significantly contribute to the weight of the shoe nor inhibit the flexibility of the shoe. The lace guide is not essential to the main object of the invention and therefore could be replaced by a conventional shoelace system along the tongue of the shoe. In that case, a separate bubble or receptacle could be mounted on the opening


116


in the upper to provide a receptacle for the chassis protrusion. Alternatively, the receptacle could be completely eliminated since the structural chassis will be effectively aligned in the upper by virtue of the fact that it occupies essentially the entire footbed. Lace guide


98


includes a base portion


99


that is sewn into the bottom side of the upper and two opposing arms


101


and


103


. The arms extend upwardly along opposite sides of upper


12


, and are sewn thereto. In one embodiment arm


101


is thinner than arm


103


, and extends along the inner or medial side of the upper, i.e., the side of the shoe having the arch, while arm


103


extends up along an outer or lateral side thereof. Lace guide


98


includes a plurality of beads


104


,


106


,


108


,


110


,


112


and


114


mounted along one side thereof. Extending between each adjacent bead is a lip such as lip


118


(

FIG. 13B

) between beads


112


and


114


behind which the lace runs. The orientation of the lower three beads is the same as the upper three beads, which is shown in cross sectional views

FIG. 13A

, FIG.


13


C and FIG.


13


D. For example, bead


110


points inwardly (FIG.


13


D), i.e., toward the toe, while bead


112


points outwardly (FIG.


13


C), opposite the direction of bead


110


, so that a lace


124


wraps around opposite sides of beads


110


and


112


. The distal beads


114


and


104


each include two holes such as holes


120


and


122


for bead


114


. The lace


124


threads through these two holes and out one side of the bead. The lace can then be tightened by pulling the lace through these two holes (and around the other beads), but the holes prevent the lace from slipping back out after the tightening force has been removed. Thus, the holes allow the lace to be first cinched and then tied without having to apply constant force to the lace to keep the lace tightened. Alternatively, a single hole can be used, in place of the two holes, so that the lace does not have to return through the second hole.




A second embodiment of the lace guide


130


is shown in FIG.


14


. In this embodiment, the beads


106


,


108


,


110


and


112


are formed separately from the main body of the guide including bubble


100


and arms


101


and


103


. Bead


106


is mounted on piece


136


, beads


108


and


110


on C-shaped piece


134


, and bead


112


on piece


132


. Each piece is sewn into the shoe upper opposite a respective notch in the lace guide (e.g., notch


138


) that receives the bead. The lace is then laced around the beads as described above. This design address as a potential problem with the lace guide of

FIG. 13

caused by the pressure applied by the lace to the arms


101


and


103


of the guide when the lace is cinched up. This pressure can cause the lace to work its way under the lips of the guide. By mounting the beads on separate pieces the pressure is exerted against these separate pieces rather than the remaining body of the lace guide. Those separate pieces (i.e.,


132


-


136


) can then be more securely fastened than the guide body.




The advantage of the lacing system shown and described herein is that the lace does not pass over and irritate and restrict connective tissue as can occur with the conventional lacing system.




Having described and illustrated the principles of the invention in a preferred embodiment thereof, it should be apparent that the invention can be modified in arrangement and detail without departing from such principles. For example, the design of the sole elements can be modified so that different portions of the upper are exposed than those shown above. An example of such an alternative design is shown in FIG.


15


. In that design the sole elements include a toe element


140


, a forefoot element


146


, and a heel element


148


. Two additional forefoot elements


142


and


144


are disposed between the toe portion and the forefoot portion. The lateral element


144


is integrally formed with the main forefoot portion


146


while the medial forefoot element


142


is a separately formed element. These elements are arranged so as to create a flex-groove therebetween as described further above. The heel portion


148


also includes a heel flex groove


150


. Unlike the forefoot flex groove, however, the heel flex groove


150


does not necessarily expose the upper. Instead the sole element is grooved in this area so as to provide a desired amount of stiffness and/or flexibility in heel area.




In a related embodiment, the chassis is attached to the external bottom surface of the upper, and the sole elements are attached directly to the chassis. Another modification coming within the scope of the applicants' invention is the use of a “flex zone” made in the structural chassis as compared with discrete notches or cuts therein. These “flex zones” can be made by varying the thickness or composition of the material used in the structural chassis to achieve the desired level of flexibility and/or stiffness. We claim all modifications and variation coming within the spirit and scope of the following claims.



Claims
  • 1. A shoe comprising:an upper including a bottom surface having a first exposed portion; at least one sole element affixed to the bottom surface of the upper, the at least one sole element comprising: a heel sole element; and a forefoot sole element spaced apart from the heel sole element, wherein the exposed portion of the bottom surface of the upper is disposed between the forefoot and heel sole elements; and a removable structural chassis in the upper, the structural chassis including a foot-supporting surface having a portion disposed above the first exposed portion of the bottom surface of the upper to provide selectable structural support for the entire shoe thereat in flexure and torsional flexibility.
  • 2. A shoe according to claim 1, wherein the structural chassis comprises a relatively stiff, resilient material.
  • 3. A shoe according to claim 1, wherein:the at least one sole element further comprises a toe sole element spaced apart from the forefoot sole element; and the bottom surface of the upper includes a second exposed portion disposed between the toe and forefoot sole elements.
  • 4. A shoe according to claim 1, wherein the foot supporting surface of the chassis comprises:a heel supporting portion; and a forefoot supporting portion.
  • 5. A shoe according to claim 4, wherein the foot supporting surface of the chassis further comprises an arch supporting portion.
  • 6. A shoe according to claim 4, wherein the chassis heel-supporting portion includes a downwardly deflectable portion.
  • 7. A shoe according to claim 6, wherein the downwardly deflectable portion includes surfaces defining at least one slot.
  • 8. A shoe according to claim 1, wherein the foot-supporting surface of the chassis comprises a cushioning material.
  • 9. A shoe according to claim 3, wherein the chassis includes surfaces defining a first flexion axis corresponding generally to a flexible portion of the second exposed portion.
  • 10. A shoe according to claim 9, wherein the first flexion axis corresponds generally to a first push-off axis of a wearer's foot passing generally through first and second metatarsal joints of the wearer's foot.
  • 11. A shoe according to claim 9, wherein the first flexion axis is aligned generally with a second push-off axis of a wearer's foot passing generally through third, fourth, and fifth metatarsal phalangeal joints of the wearer's foot.
  • 12. A shoe according to claim 9, wherein the chassis further includes surfaces defining a second flexion axis corresponding generally to the flexible portion of the second exposed portion.
  • 13. A shoe according to claim 12, wherein the second flexion axis corresponds generally to a first push-off axis of a wearer's foot passing generally through first and second metatarsal joints of the wearer's foot.
  • 14. A shoe according to claim 12, wherein the second flexion axis is aligned generally with a second push-off axis of a wearer's foot passing generally through third, fourth, and fifth metatarsal phalangeal joints of the wearer's foot.
  • 15. A shoe according to claim 12, wherein the surfaces defining the second flexion axis define a pair of opposed slots.
  • 16. A shoe comprising:an upper having a bottom wall; a plurality of spaced-apart sole elements affixed to an outer surface of the bottom wall, the bottom wall having at least one unsupported portion disposed between the sole elements; a structural chassis within the tipper having a foot-supporting surface above the at least one unsupported portion of the bottom wall of the upper to provide selectable support for the entire shoe thereat in flexure and torsional flexibility.
  • 17. A shoe according to claim 16, wherein the structural chassis comprises a relatively stiff, resilient material.
  • 18. A shoe according to claim 16, wherein the structural chassis is removable.
  • 19. A shoe according to claim 16, wherein the bottom wall is a flexible, non-supportive wall.
  • 20. A shoe according to claim 16, wherein at least one of the plurality of sole elements is affixed to the bottom wall at a location selected to underlie a portion of a wearer's foot selected from the group consisting of a calcaneus, a head of a first metatarsal, a head of a fifth metatarsal, a base of the fifth metatarsal, a head of a first distal phalange, and a head of a fifth distal phalange.
  • 21. A shoe according to claim 16, wherein the at least one unsupported portion of the bottom wall is positioned to underlie a portion of a wearer's arch.
  • 22. A shoe according to claim 16, wherein the at least one unsupported portion of the bottom wall includes a portion positioned to underlie a push-off axis defined by a line passing generally through first and second metatarsal-phalangeal joints of a wearer's foot.
  • 23. A shoe according to claim 16, wherein the at least one unsupported portion of the bottom wall is positioned to underlie a push-off axis defined by a line passing generally through third, fourth, and fifth metatarsal-phalangeal joints of a wearer's foot.
  • 24. A structural chassis for a shoe comprising:a foot-supporting surface having a heel portion, a forefoot portion, and a toe portion to provide support for a wearer's foot when installed in a shoe characterized by at least two separate sole elements; and surfaces defining a first flexion axis in the chassis corresponding generally to a forward push-off axis of the wearer's foot passing generally through first and second metatarsal phalangeal joints of the wearer's foot wherein the structural chassis further provides the shoe with selectable structural support in flexure and torsional flexibility, wherein the surfaces defining the first flexion axis define a transverse slot in the chassis.
  • 25. A structural chassis according to claim 24, wherein the structural chassis comprises a relatively stiff, resilient material.
  • 26. A structural chassis for a shoe according to claim 24 further comprising surfaces defining a second flexion axis in the chassis corresponding generally to a lateral push-off axis of a wearer's foot passing generally through third, fourth, and fifth metatarsal phalangeal joints of the wearer's foot.
  • 27. A structural chassis for a shoe according to claim 26, wherein the surfaces defining the second flexion axis define a pair of opposed notches in the chassis.
  • 28. A structural chassis for a shoe according to claim 24, further comprising an arch supporting portion.
  • 29. A structural chassis for a shoe according to claim 24, wherein at least a portion of the foot-supporting surface comprises a cushioning material.
RELATED APPLICATIONS

This application is a continuation of U.S. Ser. No. 08/892,141, filed Jul. 14, 1997, now abandoned which is a divisional of U.S. Ser. No. 08/697,184 now, filed Aug. 20, 1996 U.S. Pat. No. 5,915,820.

US Referenced Citations (29)
Number Name Date Kind
730366 Gunthorpe Jun 1903 A
2680919 Riggs Jun 1954 A
3550597 Coplans Dec 1970 A
4358902 Cole et al. Nov 1982 A
4398357 Batra Aug 1983 A
4439934 Brown Apr 1984 A
4542598 Misevich et al. Sep 1985 A
4562651 Frederick et al. Jan 1986 A
4577417 Cole Mar 1986 A
4715131 Kremendahl Dec 1987 A
4783910 Boys, II Nov 1988 A
4803747 Brown Feb 1989 A
5005300 Diaz et al. Apr 1991 A
5131174 Drew et al. Jul 1992 A
5179792 Brantingham Jan 1993 A
5317819 Ellis, III Jun 1994 A
5319866 Foley et al. Jun 1994 A
5375346 Cole et al. Dec 1994 A
5384973 Lyden Jan 1995 A
5408761 Gazzano Apr 1995 A
5425184 Lyden et al. Jun 1995 A
5524364 Cole et al. Jun 1996 A
5575088 Allen et al. Nov 1996 A
5647145 Russell et al. Jul 1997 A
5679439 Schmidt et al. Oct 1997 A
5806209 Crowley et al. Sep 1998 A
5878510 Schoesler Mar 1999 A
6023859 Burke et al. Feb 2000 A
6082023 Dalton Jul 2000 A
Foreign Referenced Citations (2)
Number Date Country
9112740 Sep 1991 WO
9413164 Jun 1994 WO
Continuations (1)
Number Date Country
Parent 08/892141 Jul 1997 US
Child 09/564842 US