WO2004002711A1 - Process for making a shoe outsole - Google Patents

Abstract

A shoe including an upper (20), a lower (insole) (30) attached to the upper (20), and an outsole (40) attached to the lower (30) is presented. In one embodiment, the outsole (40) has a ground contacting surface which includes a first section and a section section, with the first section being formed of a first material and the second setion having an outer layer formed of a material other than leather, rubber or plastic. The first section can be formed of any number of materials, such as rubber, leather, etc. The first and second sections of the outsole are formed in an injection molding process that uses one or more molds.

Description

PROCESS FOR MAKING A SHOE OUTSOLE

Cross Reference to Related Application

This application claims the benefit of U.S. patent application

serial no. 1 0/1 86,21 7, filed June 26, 2002, which is a continuation-in-

part of U.S. patent application serial No. 09/991 ,474, filed November 21 ,

2001 , which is a continuation-in-part of U.S. patent application serial No.

09/804,066, filed March 1 2, 2001 ; and is also a continuation-in-part of

U.S. patent application serial No. 09/620,422, filed July 20, 2000, all of

which are incorporated herein by reference in their entirety.

Technical Field

The present invention relates generally to a shoe and more

specifically, relates to a shoe having an outsole in which more than 50%

of the ground contacting surface is formed of a material other than

leather, rubber, or a plastic material and also relates to a manufacturing

process thereof. Background Of The Invention

A shoe is generally formed of an upper, a lower (e.g., insole)

attached to the upper, and an outsole attached to the lower. The outsole

of the shoe is the exposed portion of the sole that contacts the ground or

other supporting surface. The outsole provides many characteristics of

the shoe such as the shoe's traction and stability with respect to the

intended supporting surface. For example, the outsole of the shoe may

be provided with some type of traction elements arranged in a pattern to

provide a gripping action between the outsole and the ground or

supporting surface. The outsole should also be manufactured so that it

offers extended wear to permit the shoe to be worn for a lengthy period

of time.

Often, the outsole of the shoe is formed of a rubber material

or leather in designer shoes and the like. In men's and women's shoes,

the outsole is very often substantially smooth and this can cause traction

problems. For example, such outsoles are often very slippery because of

their smooth texture and this increases the chances that the user may

accidently slip or slide during normal use. The risk of slipping and sliding is increased significantly when the surface or supporting surface is wet

or otherwise in a slippery state.

The outsole is an important component of the shoe for an

additionally entirely unrelated reason which has gone unrecognized in the

art of shoe sole construction. As the economies of most countries

become more and more internationalized, international commercial

transactions invoke national customs tariffs that generally must be paid

when goods are shipped. Under the Harmonized Tariff Schedules of

each country, goods are classified under various categories. For

example, most footwear is classified under Chapter 64 of the United

States Harmonized Tariff Schedules which covers the importation of

goods into the United States. Within this chapter, the following major

headings are recited for footwear:

6401 Waterproof Rubber or Plastic Footwear;

6402 Other Footwear with Uppers and Outersoles of

Rubber or Plastic;

6403 Footwear with Uppers of Leather and

Outersoles

Of Rubber, Plastic, Leather, or Composition

Leather;

6404 Footwear with Uppers of Textiles and

Outersoles of Rubber, Plastic, Leather, or Composition

Leather; and

6405 Other Footwear.

Accordingly, footwear is generally classified in a given heading based

upon the material of the upper and the material of the outersole.

Consequently, the outsole plays an important role in determining the rate

of duty which is to be applied to the specific footwear article.

Depending upon the material which is used to manufacture the upper and

the sole, the rate of the duty may vary significantly. For example, the

rate of duty may range from 37.5% ad valorem for many common types

of footwear to 3% ad valorem for certain types of sandals and similar

footwear. In determining the applicability of a particular section of one

chapter of the United States Harmonized Tariff Schedules, knowledge of

specific details of the material is necessary. For example, a

classification may be based on the type of material that is present on

50% or more of the bottom surface of the shoe (outersole) that contacts

the ground.

Over many years, manufacturers have focused their

attention on improving the traction properties of shoe outsole

construction, but have not recognized that a price advantage can be had

by combining materials in the outer shoe sole construction. What is needed in the art and has heretofore not been

available is an outsole and method of manufacture thereof which offers

slip resistance and other desirable properties in addition to providing a

competitive advantage to the manufacturer based on its construction.

Summary Of The Invention

According to the present invention, a shoe including an

upper, a lower (e.g., an insole) attached to the upper, and an outsole

attached to the lower is presented. In one embodiment, the outsole has

a ground contacting surface which includes a first section and a second

section, with the first section being formed of a first material and the

second section having an outer layer formed of a material other than

leather, rubber or plastic. The first section can be formed from suitable

materials, such as rubber, leather, etc. According to one embodiment,

the outer layer is formed of a fabric material (woven or nonwoven) or a

material formed of natural fibers (i.e., vegetable or plant fibers) or metal

or cork. The outer layer of the second section preferably comprises

more than 50% of the ground contacting surface of the shoe outsole.

According to one embodiment, the outsole is preferably

formed using a molding process and, more specifically, is formed using a

one or two stage molding process. The outer layer of material is not just

layered over an existing outsole construction but rather forms an integral part of the outsole construction itself. In one embodiment, a shaped

outsole member having the outer material layer disposed on an outer

surface thereof is formed during a first molding process by meltingly

bonding the outer material to a back layer and then the shaped outsole

member is disposed in a second mold. A second molding process is

conducted and the remaining portion of the outsole is formed around the

shaped outsole member which becomes an integral part of the outsole.

The result is that an integral outsole is produced in which a substantial

amount of the ground contacting surface of the outsole is defined by the

outer material layer. Preferably, greater than 50% of the ground

contacting surface of the outsole is defined by the outer material layer.

The outsole provides increased slip resistance, is durable,

and provides a competitive manufacturing advantage.

In another aspect, the outsole is preferably formed in an

independent operation and then at a later time is attached to the lower

and/or upper of the shoe. This is in contrast to prior art shoe

construction where the upper, midsole and outsole are assembled

together and then placed into an appropriate device for causing bonding

and attachment between these members. By independently forming the

outsole, certain advantages are realized. First, the outsoles may be

formed at a completely different location and second, interchangeability

and customization are provided because one outsole may be combined and attached to any number of lowers and/or uppers. This reduces

overall manufacturing costs and increases the number of products that

may be made available.

Other features and advantages of the present invention will

be apparent from the following detailed description when read in

conjunction with the accompanying drawings.

Brief Description of the Drawings

The foregoing and other features of the present invention

will be more readily apparent from the following detailed description and

drawings of illustrative embodiments of the invention in which:

Fig. 1 is a bottom perspective view of one exemplary type

of shoe having an outsole in accordance with one embodiment;

Fig. 2 is a bottom plan view of the shoe of Fig. 1 ;

Fig. 3 is a cross-sectional view taken along the line 3-3 of

Fig. 1 ;

Fig. 4 is a bottom plan view of the shoe of Fig. 1 showing a

fabric portion of the outsole peeled back to expose a backing portion of

the outsole;

Fig. 5 is a bottom perspective view of another exemplary

type of shoe having an outsole in accordance;

Fig. 6 is a bottom plan view of shoe of Fig. 1 ; Fig. 7 is a cross-sectional view taken along the line 7-7 of

Fig. 6;

Fig. 8 is a bottom perspective view of another exemplary

type of shoe having an outsole formed in part of a cork material in

accordance with another embodiment;

Fig. 9 is a bottom plan view of the shoe of Fig. 8;

Fig. 1 0 is an exploded perspective view of a first mold

including first and second dies;

Fig. 1 1 is perspective view of a shaped fabric member

formed during a process using the first mold of Fig. 10 and for use in an

outsole of one of the prior embodiments;

Fig. 1 2 is a perspective view of a second mold in an open

position, the second mold including first and second dies, with the

shaped fabric member of Fig. 1 1 being placed in one of the first and

second dies; and

Fig. 1 3 is a perspective view of an exemplary outsole for

mating with one of a plurality of selected uppers;

Fig. 14 illustrates a home page of a fictitious Web site,

"XYZ Online";

Fig. 1 5 illustrates a first item selection page of the Web site

of Fig. 14; Fig. 1 6 illustrates a second item selection page of the Web

site of Fig. 14;

Fig. 1 7 illustrates a page of the Web site of Fig. 14 in which

a constructed shoe, formed of a selected outsole and upper, is

illustrated; and

Fig. 1 8 illustrates a page of the Web site of Fig. 1 for

ordering shoe components.

Detailed Description of the Preferred Embodiments

The present invention will be first described with reference

to Figs. 1 through 4. Fig. 1 illustrates one exemplary type of shoe 10

having an upper 20, a lower (e.g., an insole) 30 attached to the upper 20,

and an outsole 40 attached to the lower 30. The shoe 1 0 is of a style

which is commonly worn by women in both workplace settings and

social settings. The style and nature of shoe 10 is merely exemplary and

it will be understood that the present invention applies to a wide range of

types of shoes, including but not limited to men's, women's, and

children's shoes.

Fig. 3 is a cross-sectional view of the shoe 10 showing its

construction in greater detail. The upper 20 includes a soft cushioned

material, such as a fabric-backed foam 22 at an interior portion of the

shoe 10 for resiliently engaging a wearer's foot. The fabric-backed foam 22 thus serves to cushion the wearer's foot during use and reduce

impact between the foot and the surrounding environment. The upper 20

also includes an exterior cover 24, such as a high pile fabric, coupled to

the fabric-backed foam 22. For example, the exterior cover 24 may be

stitched to the fabric-backed foam 22. These two components may be

attached using other conventional techniques, such as using an adhesive

(i.e., cement or the like). It will be appreciated that the upper 20 may be

formed of a number of different materials and foam and high pile fabric

are merely exemplary materials. For example, the exterior cover 24 may

be formed of synthetic materials, leather or the like or velvet or the like,

especially for women's shoes.

The lower 30 includes a base material 32 at the interior of

the shoe 10 for engaging the wearer's foot. Typically, the base material

32 is formed of a foam or a fabric and may be formed of multiple layers.

For example, the base material 32 of the exemplary shoe 10 actually

includes a thin top layer 34 which may be formed of any number of

materials, including a fabric and a suitable plastic material. Underneath

the top layer 34 is a cushion element 35 which preferably has an

identical shape as the top layer 34. The cushion element 35 is

preferably formed of a soft cushioned material, such as a foam. It will be

appreciated that the top layer 34 and cushion element 35 can be formed

as a single integral piece. Underneath the cushion element 35, a support layer 36 is

provided. The support layer 36 is also preferably similarly or identically

shaped as the top layer 34 and the cushion element 35 and is designed

to act as a backbone of the lower 30. The support layer 36 is formed of

a rigid material so that it maintains its shape under application of force,

such as the weight of the wearer. The support layer 36 may be formed

of any number of rigid materials, such as a rigid plastic, a rigid reinforced

cardboard member, etc. The cushion element 35 is coupled to the

support layer 36 using any number of techniques, including applying an

adhesive to a backside of the cushion element 35 and then applying the

cushion element 35 to a topside of the support layer 36.

The upper and lower 20, 30 of the shoe are attached to one

another using any number of techniques. For example and as shown in

the cross-sectional view of Fig. 3, a portion of the upper 20, and more

specifically a portion 26 of the exterior cover 24, is tucked underneath

an edge of the lower 30 to secure the upper 20. The exterior cover 24

may be secured to the lower 30 by applying an adhesive (e.g., cement)

or the like to the area where the exterior cover 24 and the lower 30

meet. Other conventional techniques may be used such as stitching the

upper 20 to the lower 30. For example, a molding process may be used

so as to capture the portion 26 of the exterior cover 24 within the support layer 36, thereby causing the upper 20 to become attached to

the lower 30.

In accordance with an exemplary embodiment, the outsole

40 is made of a rigid material so as to provide support to the outsole 40

and includes an outer surface 42. The outsole 40 may have any number

of shapes depending upon the type of shoe 1 0. For example, shoe 1 0 is

a typical women's shoe and therefore includes a prominent heel 50.

When shoe 10 has a heel, such as heel 50, the heel 50 may be formed

as a separate member from the outsole 40 or the heel 50 may be

integrally formed as part of the outsole 40. In the exemplary shoe 10,

the heel 50 is a separate member which is coupled to the backing layer

42 using known techniques. Preferably, an upper portion of the heel 50,

in the form of a lip 51 , extends around a heel portion of the exterior

cover 24. This lip portion 51 is coupled to the adjacent heel portion of

the exterior cover 24 using an adhesive or the like. A bottommost

portion 53 of the heel 50 engages the ground or support surface and

therefore may be formed of a suitable material for such wear. For

example, the bottommost portion 53 may be formed of the same material

as the other portions of the heel 50 or may be formed of a different

material. The major portion of the heel 50 is preferably formed of a rigid

material, such as a rigid plastic or wood. The bottommost portion 53

may be formed of this type of material or may be in the form of a shaped rubber pad which is coupled to the other portions of the heel 50, as

shown in Figs. 1 -2.

As is known in the art, different portions of the outsole 40

of shoe 1 0 are referred to differently. The outsole 40 of shoe 1 0

includes the heel 50 formed at one end and includes a ball portion 49

formed generally at an opposite end of the shoe 10. The ball portion 49

is the portion of the outsole 40 which primarily contacts the ground

during normal use of the shoe 1 0. Between the ball portion 49 and the

heel 50, the outsole 40 includes a shank 55 which does not contact the

ground during wear of the shoe 10. The shank 55 is thus angled

upwardly away from the ground surface when the ball portion 49 and the

heel 50 are seated against the ground. The height of the heel 50

determines the angle between the shank 55 and the ground surface.

The outsole 40 also includes a shaped insert (a shaped

outsole component) 60 which forms a part of the outsole 40 and has a

predetermined shape. As best shown in Fig. 3, the shaped insert 60

includes an outer layer 62 that is formed of a first material and a backing

layer 64 that is integrally attached to the layer 62 (e.g., as by bondably

attaching, adhesively attaching, etc.). The layer 62 is formed of a

material that is not leather, rubber or a plastic material and preferably,

the layer 62 is formed of one or more materials that are selected from

the group consisting of fabric materials (woven and non-woven), materials formed of natural fibers (e.g., vegetable or plant fibers that are

woven or braided), metals, and a cork material. In one embodiment, the

outer layer 62 is formed of a non-woven fabric, such as polyester fibers

mixed with cotton. This type of outer layer 62 is therefore not produced

using a weaving process but rather is produced using other suitable

techniques for forming a non-woven fabric. For example, the polyester

fibers may be used to form a needle felt which is then impregnated with

a material before being dried and pressed. In other embodiments, the

outer layer 62 is formed of natural fibers that can be woven (braided) to

form outer layer 62. Exemplary natural fibers include plant fibers

(vegetable) that can be from a number of different sources, including

trees. For example, outer layer 62 can be formed of jute that it braided

or woven into a structure or it can be formed of cork that is cut or

otherwise processed into a layer having the desired shape and

dimensions. Further, a thin layer of metal can form the outer layer 62 or

a thin layer of wood.

Preferably, the first material that forms the outer layer 62 is

of a non-injectable type in that the first material can not be readily

injected into a mold using standard molding techniques.

It will be appreciated that the shaped insert 60 may have

any number of shapes and sizes depending upon the shoe design and other parameters such as the amount of contact between the outsole 40

and the ground or support surface.

The shaped insert 60 is disposed over a significant and

preferably a substantial portion of the outsole 40 which engages the

ground or support surface during normal use. More specifically, the

shaped insert 60 preferably occupies an area which is at least greater

than 50% of the area of the outsole 40 which contacts the ground. In

the exemplary shoe 10 shown in Figs. 1 -3, the ground contacting portion

of the outsole 40 includes the bottommost portion 53 of the heel 50 and

the ball portion 49. It will be appreciated that the percent of the ground

contacting surface of the shoe 1 0 that includes the shaped insert 60 will

depend upon a number of factors, including but not limited to the type of

shoe 1 0 (i.e., high heel or not) and the area of ground contacting surface

as a percentage of the total area of the outsole 1 0. For example, the

outer layer 62 of the shaped insert 60 preferably occupies greater than

50% to about 90% of the entire ground contacting surface of the outsole

40.

In the shoe 1 0, the shaped insert 60 is disposed within the

outsole 40 and more preferably is disposed within at least the ball portion

49 of the outsole 40. Preferably, the shaped insert 60 is integrally

formed as part of the outsole 40 as will be described hereinafter. The

bottommost portion 53 of the heel 50 is formed of a rubber or other suitable material. A gap 63 can be formed between the outer layer 62

and a surrounding edge 71 of the outer surface 42 of the outsole 40. As

shown in the figures, the outer surface 42 of the outsole 40 surrounds

the shaped insert 60. When the shaped insert 60 is disposed within the

outsole 40, an outer face of the outer layer 62 is preferably substantially

planar to the surrounding outer surface 42 of the outsole 40 so that

during use, the outsole 40 engages the ground in a relatively uniform

manner.

The backing layer 64 is preferably formed of a shape-

retaining material, for example, a rubber or plastic material and

preferably, is formed of material that can be injection molded. The

backing layer 64 and the outer layer 62 are integrally connected to one

another by any number of techniques, including using a molding process

as will be described in greater detail hereinafter or can be adhesively

attached (e.g., cemented) or mechanically fastened to one another. In

addition, the surrounding outsole 40 and the backing layer 64 may be

formed of the same material or may be formed of different materials. In

one exemplary embodiment, both are formed of a thermoplastic and

more specifically, both are formed of material that can be meltingly

(fused) bonded to one another. In another embodiment, both are formed

of a material that is referred to herein as a thermoplastic rubber (TPR). The shaped insert 60 along with the surrounding outsole 40

provide the shoe 1 0 with a slip-resistance, shape-retaining partially fabric

outsole 40. It is also contemplated that the outer surface 42 and/or the

backing layer 64 may have a tread pattern formed thereon for a

decorative purpose, a functional purpose, or both. For example, the

outer surface 42 and the layer 64 can have a tread pattern, and in the

case of a fabric outer layer 62, the fabric outer layer 62 can closely

conform to the pattern, e.g., follow the contour thereof.

The use of the shaped insert 60 also has another associated

advantage: the provision of the outer layer 62 on greater than 50% of

the ground contacting surface area of the outsole 40 enables the shoe

1 0 to be classified under a different section of the United States

Harmonized Tariff Schedules and therefore permits the manufacturer of

the shoe 10 to pay a different, lower rate of tariff duty. In other words,

the classification of the shoe 10 for tariff purposes depends, in part, on

the constituent material of the upper 20 and the constituent material of

the outsole 40 (based upon the greatest surface area in contact with the

ground). In the exemplary shoe 10, the upper 20 is formed of a textile

material and the constituent material of the outsole 40 is also a textile

material because the material which occupies the greatest surface area

in contact with the ground is the outer layer 62 which is formed of a

material other than leather, rubber or plastic. By having both the upper 20 and the outsole 40 having the

outer layer 62, the shoe 10 can be classified under "Other Footwear,

with uppers of textile materials, Other" which has a lower rate of duty

than footwear having a textile upper and an outersole formed of rubber,

plastic, leather, or composition leather. Under the current United States

Harmonized Tariff Schedules, the shoe 10 of the present invention is

classifiable under subheading 6405.20.90, which carries a 12.5% rate of

duty so long as greater than 50% of the ground contacting surface area

of the outsole 40 is occupied by the outer layer 62 which is formed of a

material other than leather, rubber, plastic (e.g., a material such as a

natural or synthetic fibrous material (woven or non-woven fabric, jute,

cork) or metal). This is significantly lower than a 37.5% rate of duty

applied to many types of footwear with outersoles of rubber, plastics,

leather or composition leather and uppers of textile materials. Thus,

associated costs for the overall manufacturing and delivering process

can be significantly reduced by decreasing the rate of duty which is

applied to the footwear (shoe 10). This results in a competitive

advantage.

The manufacture of shoe 10 and more specifically, the

outsole 40 will now be described in greater detail with reference to Figs.

1 -3 and 10-12. A two step molding process can be used to manufacture

the outsole 40. In a first molding process, the shaped insert 60 is formed. Initially, a piece of the material forming the outer layer 62 is cut

to a predetermined shape and size. Suitable materials for outer layer 62

include but are not limited to a fabric sheet, such as a non-woven fabric

(i.e., polyester fibers with cotton); a sheet formed of woven natural

fibers (i.e., jute) or the outer layer 62 can be formed of a piece of cork

that has the desired dimensions and shape. This cut piece of the outer

layer 62 is then inserted into a first mold 100. The first mold 1 00 is a

conventional mold having a first shaped die 1 02 and a second shaped die

1 04. The first and second dies 102, 1 04 have one or more cavities

formed therein which define the shape and dimensions of the shaped

fabric member 60 and are generally shaped so as to be accommodated in

the ball portion 49 of the outsole 40. The cut piece of the material

forming the outer layer 62 is held in place against the first shaped die

1 02.

The first and second dies 1 02, 104 are heated to a

predetermined temperature which permits the molding process to

proceed without damaging or destroying the material forming the outer

layer 62 (alternatively, the first and second dies are not heated). The

predetermined temperature which is required for the molding process will

depend upon a number of factors, including the type of thermoplastic

resin used in the molding process. In one exemplary embodiment, the

first and second dies 102, 104 are heated to a temperature of about 1 20° C when a thermoplastic rubber is used to form the backing layer

64. The first and second dies 102, 104 are pressed together with the

material of the outer layer 62 being held in place against the first die 1 02

and then the thermoplastic rubber is injected into the first mold 100 after

5 the thermoplastic rubber has been melted to a softened state by being

exposed to a sufficient temperature (1 20° C) .

' The injected thermoplastic meltingly bonds to the outer layer

62 by flowing within pores or interstices of the material forming the

outer layer 62 and upon cooling, a bond is formed at a boundary zone

10 between the outer layer 62 and the injected thermoplastic. For example,

the thermoplastic resin effectively bonds to a fabric material by flowing

within the interstices of the fabric. When cork is used, the thermoplastic

resin flows into the natural pores of the cork and upon cooling,

effectively creates a fused bond between the cork and the resin.

1 5 Once the shaped insert 60 has sufficiently cooled down, the

first and second dies 1 02, 104 are opened and the shaped insert 60 is

removed therefrom. Any excess material of the outer layer 62 is cut off

from the shaped insert 60 to provide for the shaped insert 60 shown in

Fig. 1 1 . As previously discussed, the shaped insert 60 includes the outer

20 layer 62 meltingly bonded to the backing layer 64.

It will also be appreciated that the thermoplastic rubber

initially comes in the form of pellets which are placed into a hopper of the like and then heated at a predetermined temperature above the

melting point causing the pellets to melt into a molten liquid of

thermoplastic rubber. This process typically does not take place right at

the first and second dies 102, 1 04 but rather at a location that is at least

slightly removed from the dies. The melted thermoplastic rubber is then

introduced into the first and second dies 1 02, 1 04 under pressure using

injection molding techniques and equipment. In this embodiment, the

first and second dies 102, 104 are not heated to high temperatures and

in fact may not be required to be heated at all, depending upon the type

of material used. So long as the molten thermoplastic rubber is

introduced into the first and second dies 102, 104 at a temperature

above its melting point and it is able to freely flow throughout the dies

1 02, 104 so as to sufficiently fill the mold area and produce the shaped

insert 60, then the first and second dies 1 02, 1 04 do not have to be

preheated before introduction of the molten thermoplastic rubber. The

heat of the molten thermoplastic rubber will cause the first and second

dies 1 02, 104 to be heated due to heat transfer therebetween.

In a second molding operation, the shaped insert 60 is

placed into a second mold 200, shown in Fig. 1 2. The second mold 200

includes a first die 202 and a second die 204. The first and second dies

202, 204 define a cavity which is generally in the shape of the entire

outsole 40. It will be appreciated that the cavity may not necessarily define the entire heel structure 50 of the outsole 40 but will likely define

the remaining portions, e.g., the shank 53 and the ball portion 49. The

shaped insert 60 (Fig. 1 1 ) is inserted into the first mold 202 with the

outer layer 62 facing a bottom section 203 of the first die 202.

Consequently, the backing layer 64 faces the second die 204 when the

second die 204 is closed.

The first and second dies 202, 204 are heated to a

predetermined temperature and are closed with respect to one another.

Once again, the predetermined temperature is a temperature at which

the first and second dies 202, 204 will not damage the outer layer 62

but will permit (1 ) the thermoplastic rubber forming the backing layer 64

to resoften (remelt) and (2) permit a second thermoplastic rubber

material to soften (melt) and flow sufficiently so that it may be injected

into the second mold 200, resulting in a fused or melt bond between the

injected material and the backing layer 64. Preferably, the

predetermined temperature of the second mold 200 is greater than the

predetermined temperature of the first mold 100. In one exemplary

embodiment, the predetermined temperature of the second mold 200 is

from about 1 60° C to about 1 70° C. It will be appreciated that suitable

molding temperatures will vary depending upon a number of parameters,

such as the operating conditions and the type of thermoplastic rubber

being used. The second thermoplastic rubber material is injected into the

second mold 200 so that if flows within the cavity formed by the first

and second dies 202, 204. Because the material forming the backing

layer 64 is softened (remelt), the heated, injected second thermoplastic

rubber material can bond with the backing layer 64 since the two

materials are selected so that they can meltingly bond to one another.

More specifically, because the thermoplastic rubber is in a softened

state, it is able to flow throughout a cavity defined by the first and

second dies 202, 204 and the heat that is present in the mold 200 (either

by heating the dies 202, 204 or by the heat that is given off by the

injected resin) causes the backing layer 64 to soften and melt. Because

the injected resin and the material forming the backing layer 64 are

bondabie to one another, a fused or melt bond results between the

melted backing layer 64 and the melted material that forms the

remaining portions of the outsole 40. In other words, the melted portion

of the backing layer 64 bonds with the injected resin along a boundary

zone which comprises a fused layer of part of the injected resin and part

of the backing layer 64. Thus, the injected resin and the material

forming the backing layer 64 must be bondable to one another according

to this embodiment. The fused bonding between the backing layer 64

and the injected resin creates a permanent, non-rupturable bond

therebetween. In one embodiment, the thermoplastic rubber material used

in both the first and second molds 1 00, 200 is the same material. It will

be appreciated that the thermoplastic rubber material used in the first

and second molds 100, 200 can be different materials. After heating the

materials in the second mold 200 for a sufficient time period, the dies

202, 204 are cooled causing the resultant outsole 40 to cool. After a

sufficient cooling period, e.g., several minutes (i.e. 6 or more minutes),

the first and second dies 202, 204 are opened and the outsole 40 is

removed.

The outsole 40 preferably has the shaped insert 60

integrally formed as a part thereof due to the bonding between the

backing layer 64 and the surrounding outsole 40. Preferably, the second

mold 200 is configured so that the outer layer 62 is not in contact with

the second thermoplastic rubber that is injected into the second mold

200. In the shoe 10, gap 63 can be formed to separate the outer layer

62 from the surrounding outer surface 42 of the outsole 40. In other

words, the outsole 40 is formed around the shaped insert 60 so that the

ground contacting surface of the outsole 40 is formed of the outer layer

62 and a portion of the outer surface 42 with both surfaces being

preferably generally planar with one another and exposed to contact the

- ground. As with the first molding process, the second molding

process may be conducted without heating of the first and second dies

202, 204 depending upon the characteristics of the second thermoplastic

rubber. If the second thermoplastic rubber is suitable for such

application, this material is injected under pressure into the first and

second dies 202, 204 in the same manner discussed above with

reference to the first molding process to form outsole 40.

After having formed the outsole 40 using the above-

described method, the outsole 40 is then incorporated into the shoe 1 0

by attaching the outsole 40 to the lower 30 to form the shoe 10. As

previously mentioned, the outsole 40 is attached to the lower 30 using

any number of techniques, including using an adhesive, such as cement,

stitching, or another suitable process, including a subsequent molding

operation in which the support layer 36 is bonded to the backing layer

64.

As shown in Fig. 4, the outsole 40 and the corresponding

manufacturing process may be modified so that a pattern 230 is formed

as part of the shaped insert 60. This pattern 230 may be decorative in

nature and also provides some functionality as it may be designed to

increase the gripping action of the outsole 40. In one embodiment, a

bottom of the first die 102 is modified by forming the pattern 230

thereon. For example, small diamond shaped objects may be formed on the first die 1 02 (Fig, 10) and the outer layer 62 is laid over the first die

102. During the first molding process, the pattern 230 is transferred

onto the shaped insert 60 as a result of the injection and pressing action

of the thermoplastic rubber. The resultant shaped insert 60 thus includes

a textured surface defined by the pattern 230.

Figs. 5-7 show another embodiment. In this embodiment, a

shoe 300 is presented and is generally in the form of a women's shoe

having an open aired toe. The shoe 300 includes an upper 31 0, a lower

320 attached to the upper 310, and an outsole 330 attached to the

lower 320.

Because of the open toe nature of shoe 300, the upper 310

is formed of a toe strap 31 2 and an ankle strap 31 4. The toe and ankle

straps 31 2, 314 may be formed of any number of suitable materials and

in one embodiment, the straps 31 2, 31 4 are formed of a backing layer

31 6 and an exterior cover 31 8. The backing layer 31 6 may comprise a

fabric backed foam or the like with the exterior cover 31 8 being

attached to the backing layer 31 6 using known techniques, such as

stitching, etc. The exterior cover 31 8 may be formed of any number of

materials, including a high pile fabric. In this embodiment, the ankle

strap 314 also includes a buckle assembly 31 9 for securing the ankle

strap 31 4 around a wearer's ankle. The toe strap 31 2 is designed to

extend across the upper portion of the foot near the wearer's toes to secure the front portion of the foot within the shoe 300. The toe strap

31 2 should be flexible so as to accommodate foots of different sizes.

The lower 320 includes a fabric-backed foam 322 and a

support member 324. The fabric-backed foam 322 provides a cushioned

surface for the wearer to place his/her foot. The support member 324

serves to provide a support platform for the wearer's foot and therefore

is formed of a rigid material. For example, the support member 324 may

be formed of a rigid reinforced cardboard member, a plastic member, a

wooden member, etc. so long as the support member 324 retains its

shape and provides adequate support to the wearer's foot.

The upper 31 0 is attached to the lower 320 (insole) using

conventional techniques, including stitching or securing ends of the

straps 31 2, 314 to the lower 320 and more specifically, by tucking these

ends between the support member 324 and the outsole 330. An

adhesive or other material may be used to secure the straps 31 2, 314 to

at least one of the support member 324 and the outsole 330.

The outsole 330 in this embodiment includes a shaped insert

340 formed as part of the outsole 330 and a heel 360. The outsole 330

also includes an outer surface 332. As best shown in Figs. 5 and 7, the

shaped insert 340 is disposed in a ball portion 331 of the outsole 330

and protrudes below the surrounding portions (outer surface 332) of the

outsole 330 such that the shaped insert 340 is the ground contacting portion of the outsole 330. During normal wear, the wearer contacts the

ground surface with the shaped insert 340 because it extends below the

surrounding sections of the outsole 330.

The heel 360 is attached to the outer surface 332 using

conventional techniques, e.g., use of an adhesive, and a bottommost

portion 362 of the heel 360 preferably includes a rubber or plastic piece

which reduces wear of the heel 360 and provides a gripping surface. A

shank portion 363 of the outsole 330 is formed between the heel 360

and the ball portion 331 . The shank portion 363 is defined by the outsole

330 and does not include the shaped insert 340. The shaped insert 340

is thus only provided on sections of the outsole 330 which contact the

ground surface during normal wear.

As best shown in Fig. 7, the shaped insert 340 is formed of

an outer layer 343 and a backing layer 345. As will be described

hereinafter, the backing layer 345 is preferably integrally bonded to the

material forming the outsole 330 and preferably, the layer 345 and the

outsole 330 are formed of the same material so that it will appear to the

wearer that the outer layer 343 is simply attached to a particular section

of the outsole 330. The backing layer 345 is the material lying

immediately underneath the outer layer 343 and serves to define a

platform extending downwardly from the surrounding sections of the

outsole 330. In this manner, the outer layer 343 is only in contact with the backing layer 345 and not the surrounding sections of the outsole

330.

In this embodiment and in accordance with the present

invention, greater than 50% (as measured in terms of area) of the ground

contacting sections of the shoe 300 include the shaped fabric member

340. In the exemplary shoe 300 shown in Figs. 5-7, the ground

contacting surface of the outsole 330 includes the bottommost portion

362 of the heel 360 and the ball portion 331 . More specifically, besides

the heel portion 362, the only other portion of the outsole 330 which

contacts the ground surface is the shaped insert 340. Thus in this

particular embodiment, the shaped insert 340 comprises a substantial

portion of the ground contacting surface of the outsole 330 as the outer

surface 332 does not contact the ground surface.

The manufacture of the shoe 300 is preferably done in a

similar or the same manner as the manufacture of the shoe 10 described

in reference to Figs. 1 0-1 2. More specifically, the manufacture is

preferably a two stage molding process using the first and second molds

1 00, 200. In this embodiment, the bonding between the backing layer

345 and the outsole 330 is clearly shown in the cross-sectional view of

Fig. 7 which illustrates that a boundary zone (i.e., a fused layer) is

formed between the backing layer 345 and the injected resin material

that forms the surrounding portions of the outsole 330. After forming the shaped insert 340 using the first mold 1 00, the insert 340 is then placed

in the second mold 200 to form the outsole 330 illustrated in Figs. 5-7.

During the second molding process, the outer layer 343 is not in contact

with the second thermoplastic rubber that is added to the second mold

200 to form the remaining sections of the outsole 330 but rather the

second thermoplastic rubber is disposed over and around the heated

backing layer 344 (preferably a thermoplastic rubber also) .

Now referring to Figs. 8-9 which illustrate yet another

embodiment. In this embodiment, a shoe 400 is presented and generally

includes an upper 410, a lower 420, and an outsole 430. The shoe 400

is in the form of a walking or leisure type shoe instead of the more

formal shoes shown in Figs. 1 -7. The upper 410 and lower 420 have

conventional constructions and are attached to one another using

conventional techniques. The outsole 430 is also attached to the lower

420 using conventional techniques.

According to this embodiment, the outsole 430 includes a

shaped insert 440 and a surrounding outsole surface 450 that is formed

around the insert 440 when an injection molding process is used. The

shaped insert 440 has a an outer layer 442 formed of a cork material

disposed on an outer surface thereof so that the outer layer 442

contacts the ground surface or the like during normal wear of the shoe

400. Bottom portions (surface 450) of the outsole 430 surrounding the shaped insert 440 are formed of any number of suitable materials

including but not limited to leather, plastic and rubber materials. The

bottom portions of the outsole 430 are preferably generally planar with

respect to the shaped insert 440 to define a substantially planar ground

contacting surface of the outsole 430. In this embodiment, the shoe 400

includes two shaped inserts 440, one disposed proximate a heel portion

402 of the shoe 400 and the other disposed proximate to a toe portion

404 of the shoe 400. A gap 444 is formed between the outer layer 442

and the outer surface 432 of the outsole 430 in one exemplary

embodiment.

The outer layers 442 of the shaped inserts 440 occupy an

area which is at least greater than 50% of the area of the outsole 430

which contacts the ground surface. Preferably, the shaped inserts 440

occupy greater than 50% to about 90% of the entire ground contacting

surface of the outsole 430. The shaped inserts 440 may have any

number of shapes and sizes so long as the outer layers 442 of the

shaped inserts 440 occupy greater than 50% of the surface of the

outsole 430 which contacts the ground surface during normal wear.

The shoe 400 can be formed using the manufacturing

process described herein with reference to Figs. 10-1 2. In other words,

the shaped inserts 440 are formed using a first molding process and then

are inserted into the second mold 200 (Fig. 1 2) where a second molding process is conducted. During the second molding process, the outsole

330 is formed around the inserts 440 so that the shaped inserts 440 are

formed as integral parts thereof. The result is that the outsole 430 of

the shoe 400 includes as a part of the ground contacting surface thereof,

the outer layers 442, while surrounding portions of the outsole 430 are

not formed of the same material that form the outer layers 442 but

instead are formed of other suitable materials. It will be appreciated that

while thermoplastic rubbers are preferred for use in the molding process,

other types of materials may be used so long as they produce the shaped

fabric member having the characteristics described herein with reference

to the various embodiments.

In yet another embodiment, a single molding process is used

instead of the aforementioned two stage process. In other words, the

outsole is first formed by cutting a piece of the material forming the

outer layer 62 (Fig. 1 ) to have a predetermined size and shape and then

this cut piece is placed into a mold. It will be understood that one or

more cut pieces of material that each forms an outer layer 62 can be

used to form the outsole 40 (Fig. 1 ) using the manufacturing process of

this embodiment. Each cut piece is then placed into selected portions of

the mold. For example, the cut piece is preferably disposed in a shaped

recess formed in the bottom of one of the dies. The other part of the dies is formed so as to have a shape and dimensions for forming the rest

of the outsole 40.

The dies of the mold are closed and then a thermoplastic

rubber is injected into the mold. The mold can be of a hot type in which

the dies are preheated prior to injecting the thermoplastic rubber or it

may be a cold type in which the dies are not preheated (in this instance,

the thermoplastic rubber is of sufficiently high temperature, that it flows

throughout the dies). The injected molded thermoplastic rubber flows

into the closed dies and flows over the one or more cut pieces of

material (that forms the outer layer(s) 62) that are laid in select locations

of one of the dies. The cavity formed by the closed dies represents the

shape and size of the outsole 40 that results from this manufacturing

process.

The molded outsole structure is then permitted to cool down

within the mold. Once the outsole 40 has cooled down, the dies are

opened and the outsole 40 is removed. The resulting outsole 40 has the

outer layer 62 integrally formed as a part thereof due to the bonding

between the outer layer 62 and the thermoplastic rubber used to form

the surrounding outsole 40 as a result of the thermoplastic rubber

flowing into the pores and interstices of the outer layer 62. The ground

contacting surface of the outsole 40 is formed of the outer layer 62 and

the injected thermoplastic rubber material. Unlike the previously-described embodiments that use a two

mold system, the manufacturing process according to this embodiment

only uses a single mold system. This reduces equipment cost, etc.

In an alternative embodiment, a one step injection molding

process is used to form an outsole that has a recessed section formed

therein. For example, one of the dies can have a raised portion that

corresponds to the recessed section of the outsole. After the injection

molding process is completed, an outsole is formed and includes a ground

contacting surface with one or more recessed sections formed therein.

Each recessed section is designed to receive a complementary insert

that includes a backing layer (i.e., layer 64) integrally formed with an

outer layer (i.e., outer layer 62) . The insert is securely held within the

recessed section by any number of different methods, including but not

limited to applying an adhesive (i.e., cement) to the backing layer and

then disposing the backing layer against a floor of the recessed section

so that the backing layer securely attaches to the floor. In addition, the

backing layer and the floor can be bondably attached by selectively

heating the floor and the backing layer to cause remelt and then

combining the two together to form a fused, melt bond between the two

layers. After securely attaching the insert to the floor in one of the

above manners, the outsole looks like outsole 40 of Fig. 1 . Fig. 1 3 illustrates yet another aspect of an outsole 500

which like the other embodiments includes a component (outer layer)

502 (shown in phantom) that is integrally formed as part of the outsole

500. Because the outsole 500 is preferably manufactured using the

previously-described one or two stage molding processes, the outsole

500 is manufactured at a first time and then later attached to an upper

51 0 to form the shoe 501 at a second later time. While this embodiment

is discussed in terms of attaching the outsole 500 to an upper, it will be

understood that this covers the attachment of the outsole 500 to a

lower/upper construction, as is commonly used. However, for purposes

of illustration and simplicity only, this embodiment is discussed in terms

of attaching the outsole 500 to the upper. The time difference between

the first time and the second time may be as short as a few minutes or

may be as great as days, weeks, months, etc. Because the outsole 500

is not formed during the process in which the shoe 501 itself is formed,

the outsole 500 may be manufactured at a location remote from where

the shoe 501 is later formed by attaching the upper to the outsole 500.

This provides a number of advantages as remote manufacturing sites

may be used, as well as the ability to have different manufacturers

produce and perform these separate operations. This is much different

than prior art shoes where all the parts were assembled and then

subjected to certain processes which caused the parts to be attached to one another, i.e., a heating operation during a single manufacturing

process. In other words, the outsole in these shoes is not independently

formed and then attached to the other components of the prior art shoe.

Another advantage of the present method is that it offers a

wide degree of interchangeability. More specifically, one outsole 500

may be attached to any number of uppers and thus a great number of

shoe styles incorporating the outsole 500 may be offered to the

consumer. For example, a shoe manufacture may purchase the outsole

500 and then attach the outsole 500 to a lower/upper associated with

that particular manufacturer. This operation is not overly complex

because the lower/upper are attached using conventional techniques. It

will be appreciated that this permits the outsoles 500 to be

manufactured and distributed by themselves to those shoe

manufacturers that wish only to purchase the outsoles 500 and then

construct the shoe using their components.

In addition, the outsole 500 of a first configuration may be

attached with any one of a multiple number of uppers having a variety of

different styles. This results in a number of different shoe styles being

formed using the same outsole 500 of the first configuration. Fig. 1 3

illustrates the outsole 500 being adapted to be attached to one of a first

upper 51 0, a second upper 520, and a third upper 530. Because the outsole 500 is independently formed and

uppers 51 0, 520, 530 are independently formed, there is a great degree

of interchangeability in that outsoles 500 may be mixed and matched

with different uppers, including uppers 510, 520, 530, with relative ease.

This is marked improvement over conventional shoes in which each

component of the shoe was configured for use in one particular shoe

style. In contrast, the present outsoles 500 permit a degree of

customization that has heretofore not been available. Of course, it will

be appreciated that some outsoles 500 (such as the type for a woman's

high heeled shoe) will not be appropriate for use with some uppers that

have configurations that are not compatible (for example, those that are

configured for attachment to a flat outsole) . In order for the outsole 500

to be compatible with the upper, the outsole 500 must engage the

ground surface in a normal manner which permits the wearer to walk in

the shoes without experiencing any difficulties.

Fig. 13 illustrates just one of the many combinations that

are available for constructing a shoe that has a previously-formed outsole

that is then later attached to any number of uppers to create different

types of shoes.

In yet another aspect, a method of conducting business,

more particularly, a method of customizing shoe design is provided. The

method includes the steps of offering a plurality of outsole configurations from which to select, offering a plurality of shoe lower/upper designs

from which to select, selecting one outsole configuration and one

lower/upper configuration, determining if the selected outsole

configuration is compatible with the selected lower/upper configuration,

and indicating whether or not the selected outsole configuration is

compatible with the selected lower/upper configuration.

Because the outsole is formed independently from the

lower/upper, a particular outsole configuration that appeals to an

individual may be selected. As previously-mentioned, the outsoles can

be manufactured, stored, and transported independently of the other

components of the assembled, finished shoe. This versatility permits the

individual to select one outsole and then select a lower/upper that the

user would like to mate with the selected outsole to form the shoe.

Selection may be done using any number of different mediums, including

using an interactive computer system or by manually selecting the

components from a printed catalog or the like.

After a selection of each has been made, the compatibility

of the selected components is assessed. The assessment may be based

on a number of different parameters, including type of shoe (i.e., men's,

women's, children's) and shoe style (i.e., flat outsole vs. curved outsole).

For example, a flat outsole is compatible only with those lowers/uppers

that are shaped to be attached to a flat outsole. The same holds true for curved outsoles for use with lowers/uppers that are shaped to be

attached thereto. If a computer system is used, a computer generated

image is preferably made of the finalized shoe and then displayed to the

user.

In one embodiment, this method may be implemented using

a web site. For example, a home page may be constructed and

displayed using a conventional browser. The browser includes navigation

buttons to move forwards and backwards among various web pages and

provides further functionality including secure transmission of documents

over the Internet or other distributed computer network, for example,

between the browser (at the client side) and a web server, such the

server hosting the home Web site.

Fig. 14 shows an exemplary web page 600 which includes

information provided at the web site, such as description of the goods

and services that are available for purchase by the consumer. In this

particular application, the web page 600 is an initial screen at a web site

that permits custom construction and ordering of shoe outsoles and other

shoe components, e.g., uppers, that are used in the construction of the

shoe.

For example, web page 600 includes contact information

610 about the manufacturer of the shoe components, an options menu

620 for selecting a general shoe type. In other words, the user can select a shoe department for purposes of viewing the various shoes

offered. For purpose of illustration, Fig. 1 4 only illustrates a men's and a

women's department; however, it will be understood that other

departments, such as children's, babies, etc. may be available. The web

page 600 contains other conventional items, such as a tool bar 601 , a

log in section 603, and a promotional area 605.

After the user has entered the particular department, the

user begins construction of the shoe by selecting an outsole. Fig. 1 5

illustrates a first item-selection page 620 for selecting outsole 500. The

user is given a number of options that are available in menus (i.e., the

illustrated pull down type menus). For example, a color menu 630, a size

menu 640, and quantity menu 650 are provided and permit the user to

make various selections before proceeding with ordering the selected

outsole using conventional Web site methods, including clicking on a

button 650. In this case, the button 650 is labeled as an "enter" button

but it can likewise be labeled as a "continue" button, etc. A shipping

menu 660 is also provided for the user to input the necessary shipping

information if the user wishes to directly order at this point and bypass

the other Web pages of the system. For example, the user may be

reordering a certain outsole or may be adding to an order and therefore

does not have to view available uppers, etc. Page 620 also has a tool

bar 679 that presents the user with various options, such as a directory feature which when activated, displays a directory for the user; other

features, such as a help feature are provided.

The page 620 preferably also contains other information,

such as a representation 670 of the selected outsole and further pricing

information 672, and available colors and sizes 674 can be depicted for

the user with the colors also being graphically indicated in a section 676.

To permit the user to navigate amongst the available

outsoles, conventional mechanisms are provided, such as browse

functionality 680 that permits the user to browse forward 682 and

browse backward 684. Preferably, each time the user browses either

forward or backward, the selected outsole is graphically illustrated on

the web page. This permits the user to browse much faster, as the user

can scan the illustrated outsoles until coming to one that is of interest. If

the user wishes to proceed directly with purchasing the uppers without

having to go through the additional Web pages, the user can click on the

button 660 and subsequently, the user inputs conventional shipping

information, including shipping address, billing address, payment

information, etc.

Once the user has selected an outsole (i.e., by clicking

button 650), the user then browses through various uppers that meet

certain prescribed characteristics that permit the uppers to be used with

the selected outsole. The system is designed, in one embodiment, so that the uppers that are made available to the user for browsing depend

from the outsole selected. In other words, the user will not be permitted

to view or browse through any uppers that are not complementary to the

selected outsole. Fig. 16 illustrates a second item-selection page 700 for

selecting one or more uppers for combination with the previously

selected outsole to form the completed shoe. It will be understood that a

single page 700 can be used to illustrate one upper or, as is shown in Fig.

16, one web page can be used to illustrate multiple uppers.

In the illustrated embodiment, Fig. 16 includes three

different types of uppers 510, 520, 530, respectively, that can be

combined with the outsole 500 of Fig. 1 5. In addition, to the previously

mentioned menu options, the user is provided with another menu option

710 that permits the user to highlight and select one of the uppers that is

shown. For example, the menu 710 can identify the uppers by any

number of means including by name (i.e., style name) or by a reference

number (i.e., style number). Once the user has selected an upper and

supplied all necessary information, such as color, size, and quantity, the

user then proceeds to the next step by pressing the "enter" button 650.

It will be appreciated that the system can be configured so that the user

does not have to enter the color and the size of the upper as default

settings for these selections can be directly linked to the inputted color

and size selections that were previously made relative to the outsole. In other words, the user does not have to enter the color and size of the

upper as the default settings for these selections will match those

previously made relative to the outsole. It will also be appreciated that

the color of the upper can differ relative to the color of the outsole. In

other words, the outsole and upper do not have to be the same color and

the user when constructing the shoe can select one color (i.e., black) for

the outsole and another color (i.e., navy) for the upper. This permits a

vast number of different shoe constructions and appearances to be

possible.

Once the user selects the upper, the user then proceeds by

pressing the button 650. Referring to Fig. 1 7, next another web page

800 is shown in which the assembled shoe is shown to the user. The

assembled shoe is a combination of the previously-selected upper and

outsole. If the user is satisfied, the user can continue and order the

various components by pressing on the order button 720. Because the

user has already previously entered the color, size and quantity of each

particular upper and outsole, the web page that is accessed after the

user has clicked on the order button 720 preferably lists these inputted

quantities. However, the user is permitted to modify this information by

simply accessing one of the menus and altering the selected information.

Fig. 1 8 illustrates a page 900 that is displayed after the user presses the

order button 720 or after the user has selected the button 660 in a previous page. Traditional ordering options are also provided to the user,

such as shipping information 902 and payment (billing) information 904.

Once the user provides this information 902, 904, the transaction is

completed and the user can exit or continue by selecting an appropriate

button that is located on the tool bar or elsewhere on the page 900.

Thus, it will be appreciated that the user can order a

quantity of a single outsole and then order different types of uppers for

assembly with the selected outsole. Further, the user can order multiple

types of outsoles and multiple types of different uppers for mixing and

matching with the ordered outsoles. The present system also

automatically discards outsole/upper combinations that are not possible

so that the user can not order two components that are not

complementary to one another. In the above exemplary embodiment,

this occurs after the outsole is selected by the user and a search is

conducted in a database for complementary uppers. However, it will be

appreciated that the system can also be configured so that the user first

selects an upper and then a search of complementary outsoles is

conducted and displayed to the user. This embodiment permits the user

to first select what may be regarded as the more visually dominant part

of the shoe and then the user is supplied with the various outsoles from

which a selection is to be made. The above system therefore provides graphical

representations that are shown for all of the available outsoles, uppers,

and other components. This permits the user to visualize how any given

outsole will look with one of the available uppers. Moreover, the display

illustrates what the resulting shoe looks like when the selected upper and

outsole are combined and attached to one another.

It will be appreciated that once the user selects one outsole,

a search for complementary uppers is conducted in a database

containing all upper constructions that are offered by not only this

particular manufacturer but also other manufacturers. Whether an upper

is complementary to an outsole is predetermined and included and

preferably, a generic upper is provided that can be combined with one or

more outsoles of various types. For example, the generic upper can be

provided with one or more features that permit it to be adapted for use

with several or more outsoles. For example, the upper can be provided

with an incomplete construction (i.e., a loose seam is present) to permit

the upper to be manipulated and then attached to different types of

outsoles. As part of the attachment process, the upper is then

completely constructed, e.g., as by sewing all loose seams, etc.

If the selected outsole is one that is generally designated as

having an intended use as part of a woman's high heeled shoe, then the

compatible lower/uppers will be those that are likewise constructed for a woman's high heeled shoe. For example, the outsole for such a high

heeled shoe is typically not planar but rather is curved to accommodate

the heel and therefore, the lower/upper needs to capable of

accommodating and fitting along such a curved section. The advantage

of having outsoles and uppers that may be mixed and matched is that the

same outsole may be matched with a number of uppers to generate a

plurality of different looking shoes. The provides the consumer with

more options and reduces manufacturing costs as outsoles may be made

independently of the other components and then later attached to

selected uppers at a later time.

The following Examples are to merely illustrate exemplary details

of the present outsole construction and are not intended to limit the

scope of the present invention.

Example 1

According to one embodiment, the outsole is formed by first

placing one or more pieces of a first material that form at least greater

than 50% of the ground contacting surface into a mold. For example,

the first material can be a non woven fabric or can be a cork material.

The mold is then closed and rotated to an injector that injects a

thermoplastic rubber (TRR) in a past state into the mold. The TPR is injected into the mold at a temperature from about 1 50° C to about 1 90°

C. At the same time that the TPR is injected into the mold, air is also

injected into the mold through an inlet so as to mix with the injected TPR

to achieve a looser density to make it lighter. In other words, the TPR is

blown. Before the mold is open, the air is let out through an outlet. At a

predetermined time (e.g., 1 minute after injection completed), the mold is

open and the formed outsole is removed therefrom. The fabric

represents a ground contacting surface of the outsole with the other

sections of the outsole being formed of TPR around the fabric. Thus, TPR

surfaces also form ground contacting surfaces; however, the TPR

surfaces represent 50% of less of the entire ground contacting surface.

Example 2

According to one embodiment, the outsole is formed using a

rotating TPR injecting machine by first placing one or more pieces of a

first material that form at least greater than 50% of the ground

contacting surface into a mold. For example, the first material can be a

non woven fabric or can be a cork material. The mold is then closed and

rotated to an injector that injects a thermoplastic rubber (TRR) in a past

state into the mold. The TPR is injected into the mold at a temperature

from about 1 80° C to about 200° C. At a predetermined time (e.g, 6 minutes after injection completed), the mold is open and the formed

outsole is removed therefrom. The fabric represents a ground contacting

surface of the outsole with the other sections of the outsole being

formed of TPR around the fabric. Thus, TPR surfaces also form ground

contacting surfaces; however, the TPR surfaces represent 50% of less of

the entire ground contacting surface.

Example 3

According to one embodiment, the outsole is formed by first

heating a mold to a temperature from about 1 40° C to about 1 50° C and

then placing one or more pieces of a non woven fabric (or other material

that is not leather, rubber or plastic) into the mold. The non woven fabric

forms at least greater than 50% of the ground contacting surface. The

mold can include a pointed needle formed as part of the mold to hold the

fabric in place. The mold is then closed and a thermoplastic (i.e.,

polyurethane) (TPU) is injected into the mold. At a predetermined time

(e.g, 1 1 seconds after injection completed), the mold is opened and the

formed outsole insert is removed therefrom. The outsole insert has a

fabric outer layer and a backing layer formed of TPU. Any excess

material is trimmed off by hand.

Next, a second mold is opened and a lubricant (i.e., silicon)

is sprayed thereon. The shaped insert is inserted into the second mold with the fabric material facing the mold surface. Polyurethane in its

liquid state is poured into the mold within about 5 second of placing the

shaped insert in the second mold. The second mold is then closed and a

can be heated using know techniques. The liquid state polyurethane

solidifies on its own at the temperature of about 1 30° C in the mold for

about 1 0 minutes through a heating channel or heating process. The

mold is then opened and the formed outsole is taken out and any excess

material is trimmed off. The polyurethane that is added to the second

mold forms the outsole sections that surround the shaped insert and

during the second molding process, at least a portion of the backing layer

(TPU) of the shaped insert melts and a fused bond is formed between the

backing layer and the TPU forming the rest of the outsole. The fabric

represents a ground contacting surface of the outsole with the other

sections of the outsole being formed of TPU around the fabric. Thus,

TPU surfaces also form ground contacting surfaces; however, the TPU

surfaces represent 50% of less of the entire ground contacting surface.

Example 4

In another embodiment, an outsole formed of rubber and a

fabric material is formed. One or more pieces of non woven fabric

pieces are cut and also the rubber is cut (e.g., in the form of a wide

strap) . A mold is opened and the fabric piece(s) is placed into the mold. The cut rubber is placed on top of the non woven fabric and the mold is

closed. The mold is then placed in a heater (similar to an oven) and the

heater temperature is set between about 160° C and about 1 0° C. The

mold is left in the heater for about 3 to 5 minutes and then is removed

from the heater. The mold is opened and the formed outsole is taken out

and any excess rubber is trimmed off. The fabric represents a ground

contacting surface of the outsole with the other sections of the outsole

being formed of rubber around the fabric. Thus, rubber surface also

forms a ground contacting surface; however, the rubber surface

represents 50% of less of the entire ground contacting surface.

While the invention has been particularly shown and

described with reference to preferred embodiments thereof, it will be

understood by those skilled in the art that various changes in form and

details may be made therein without departing from the spirit and scope

of the invention.

Claims

WHAT IS CLAIMED IS:

1 . A method for manufacturing a shoe, the method

comprising:

providing a shoe upper;

forming an outsole having a ground contacting surface by:

inserting a piece of a first material into a mold, the

first material being non-injectable;

injecting an injection-moldable material into the mold

and operating the first mold to form the outsole by moldably bonding the

piece of first material to the injection moldable material,

wherein a ground contacting surface of the outsole

includes the piece of first material and a section formed by the injection

moldable material; and

attaching the outsole to the shoe upper.

2. The method of claim 1 , wherein the first material is selected

from the group consisting essentially of a nonwoven fabric, a woven

fabric, woven natural fibers, braided natural fibers and metal.

3. The method of claim 1 , wherein the first material comprises

cork.

4. The method of claim , wherein the injection-moldable

material comprises a material selected from a thermoplastic rubber,

polyurethane, and rubber.

5. The method of claim 1 , wherein the first material is a

material other than leather, plastic, and rubber.

6. The method of claim 1 , wherein the first material occupies

greater than 50% of the ground contacting surface.

7. The method of claim 1 , comprising the additional steps of:

forming one or more recessed sections in the mold for receiving the

piece of first material and injecting the injection -moldable material so as

to cover an exposed face of the first material.

8. The method of claim 1 , comprising the additional steps of

operating the mold in one of a hot state in which mold dies are heated

prior to injecting the injection- moldable material and a cold state in

which the mold dies are free of any heating prior to injecting the

injection-moldable material.

9. A method for manufacturing a shoe, the method

comprising:

providing a shoe upper;

forming an outsole having a ground contacting surface by:

inserting a piece of a first material into a mold, the

first material being non-injectable;

injecting a first injection-moldable material into the

mold and operating the mold so that the first injection-moldable material

meltingly bonds to an exposed surface of the piece of first material;

permitting the injection-moldable material to cool in

the mold sufficient to form an insert that has an outer layer defined by

the piece of first material and a shaped backing layer that is formed of

the first injection-moldable material;

injecting a second injection-moldable material over an

exposed section of the backing layer to form a remaining structure of the

outsole in which a fused bond is created between the second injection

moldable material and the exposed section of the backing layer;

wherein a ground contacting surface of the outsole

includes the piece of first material and a section formed by the second

injection moldable material; and

attaching the outsole to the shoe upper.

1 0. The method of claim 9, wherein the first material is

selected from the group consisting essentially of a nonwoven fabric, a

woven fabric, woven natural fibers, braided natural fibers and metal.

1 1 . The method of claim 9, wherein the first material

comprises cork.

1 2. The method of claim 9, wherein each of the first and

second injection-moldable materials comprises a material selected from

the group consisting essentially of a thermoplastic rubber, polyurethane,

and natural rubber.

1 3. The method of claim 9, wherein the first and second

injection moldable materials are the same material.

1 4. The method of claim 9, wherein the first and second

injection moldable materials are different materials.

1 5. The method of claim 9, comprising the additional steps

of forming the insert in a first mold and then transferring the formed insert to a second mold where the second injection-moldable material is

injected over an exposed section of the backing layer.

1 6. The method of claim 9, wherein forming the fused bond

comprises forming a fused layer that is formed of a portion of the

exposed backing layer and a portion of the second injection moldable

material.

17. The method of claim 9, wherein the insert is positioned

with the mold such that only the backing layer is exposed, thereby

preventing the second injection-moldable material from overlying the

piece of first material.

18. The method of claim 9, wherein the second injection-

moldable material comprises a thermoplastic rubber (TPR) and the step of

injecting the second injection-moldable material includes the step of

introducing air into the injected second injection-moldable material so as

to create a blown form of TPR.

1 9. A method for manufacturing a shoe outsole, the

method comprising: inserting a piece of a first material into a mold, the first

material being non-injectable;

injecting a first injection-moldable material into the mold and

operating the mold so that the first injection-moldable material bonds to

an exposed surface of the piece of first material and whereupon cooling,

an insert is formed that has a ground contacting outer layer defined by

the piece of first material and a shaped backing layer that is formed of

the injection-moldable material;

injecting a second injection-moldable material over an

exposed section of the backing layer to form a remaining structure of the

outsole in which a fused bond is created between the second injection

moldable material and the exposed section of the backing layer; and

wherein a ground contacting surface of the outsole includes

the piece of first material and a section formed by the second injection

moldable material.

20. The method of claim 1 9, wherein the first material

is selected from the group consisting essentially of a nonwoven fabric, a

woven fabric, woven natural fibers, braided natural fibers and metal.

21 . The method of claim 1 9, wherein the first material

comprises cork.

22. The method of claim 1 9, wherein each of the first

and second injection-moldable materials comprises a thermoplastic

rubber.

23. The method of claim 19, wherein the first and

second injection moldable materials are the same material.

24. The method of claim 19, wherein the first and

second injection moldable materials are different materials.

25. The method of claim 19, wherein the step of

injecting the second injection-moldable material is conducted in a

separate mold than the mold used to form the shaped insert.

26. A shoe formed in accordance with the method of

claim 9.