Sustainable bra garment and improved bio-based open cell foam pad portions

Abstract

A sustainable bra garment that includes first and second cup portions that are formed of one or more recycled flexible materials and having first and second cushioning support pads formed of a bio-based foam material The first and second cushioning support pads are configured to be coupled with the first and second cup portions, respectively. The front surface of each pad has a generally convex shape and the back surface of each pad has a generally concave shape. Each of the pads is formed of a bio-based material, such as a sugar cane-based open cell foam that has hardness and density values that provide both cushioning and support to breasts of a wearer of the sustainable bra garment. The cushioning support pads may be used with a bra garment or with other garments such as swimwear and other apparel where bra support pads can be incorporated.

Claims

1. A bio-based cushioning support pad for use in a bra garment or other garment, comprising: a pad portion formed of one or more bio-based foam materials, comprising at least about 40-85% bio-based EVA and bio-based PE formed substantially from sugar cane-based ethylene; said bio-based EVA and PE combined with at least; a peroxide-based initiator, and a foaming agent; said bio-based EVA, bio-based PE, peroxide-based initiator and foaming agent mixture formed into a substantially flat sheet by methods comprising; the addition of heat to a temperature of between about 105? C. to about 130? C. to form a melt mixture, extruding said melt mixture to form said mixture into a shape, maintaining said shape during extrusion at a temperature of between at least about 60? C. to about 90? C., and compressing said shape to form a substantially flat sheet; expanding the volume of said substantially flat sheet by a heating method comprising; heating said sheet to between about 135? C. to about 150? C. for between about 30 to 45 minutes to obtain a substantially cross-linked foam material with limited volumetric expansion, heating said sheet to between about 160? C. to about 185? C. for between about 90 to about 150 minutes to obtain a substantial volumetric expansion, wherein a bio-based foam block is formed; crushing said bio-based foam block through a multiple compression roller process comprising; crushing said bio-based foam block between compression rollers at least about 4 times, to release a substantial volume of air from inside said bio-based foam block, wherein an open cell foam block is formed; cutting said open cell foam block into sheets; shaping said bio-based open cell foam sheets into pad portions, said pad portions formed within a mold into a shape having an inner surface substantially concave in shape and an outer surface substantially convex in shape.

2. The bio-based cushioning support pad of claim 1, wherein the said bio-based EVA and PE is also combined with an olefin block copolymer.

3. The bio-based cushioning support pad of claim 1, wherein said bio-based foam material is comprised of at least about 40-85% bio-based EVA formed substantially from sugar cane-based ethylene.

4. The bio-based cushioning support pad of claim 3, wherein the bio-based EVA is combined with an olefin block copolymer.

5. The bio-based cushioning support pad of claim 1, wherein following the compression roller process said foam block is heated to between about 165? C. to about 175? C. for between about 40 to about 50 minutes to substantially restore the thickness of said foam block.

6. The bio-based cushioning support pad of claim 1, wherein said pad portion having a Shore 00 hardness value of at least about 20 to about 70.

7. The bio-based cushioning support pad of claim 1, wherein said pad portion is comprised of a bio-based carbon content of between about 40% to about 90%.

8. The bio-based cushioning support pad of claim 1, wherein said sheet formed by said cutting method is comprised of an open cell foam having a density in the range of about 0.020 to about 0.045 g/cm3.

9. The bio-based cushioning support pad of claim 1, wherein said pad portion is formed by a molding method comprising; heating said bio-based open cell foam sheets within a mold to between about 70? C. to about 120? C. for a first press of between about 80 to about 140 seconds in duration, re-heating said bio-based foam sheets within said mold to between about 20? C. to about 60? C. for a second press of between about 60 to about 120 seconds in duration, and cooling said bio-based foam sheets within said mold to about room temperature for between about 30 seconds to about 70 seconds in duration; wherein said partial pad portion is formed within said mold into a shape having an inner surface substantially concave in shape and an outer surface substantially convex in shape.

10. A method for making bio-based cushioning support pads for use in a bra garment or other garment, comprising: At least one pad portion formed of one or more bio-based foam materials, comprising at least about 40-85% bio-based EVA and bio-based PE formed substantially from sugar cane-based ethylene; said bio-based EVA and PE combined with at least; a peroxide-based initiator, and a foaming agent; said bio-based EVA, bio-based PE, peroxide-based initiator and foaming agent mixture formed into a substantially flat sheet by methods comprising; the addition of heat to a temperature of between about 105? C. to about 130? C. to form a melt mixture, extruding said melt mixture to form said mixture into a shape, maintaining said shape during extrusion at a temperature of between at least about 60? C. to about 90? C., and compressing said shape to form a substantially flat sheet; expanding the volume of said substantially flat sheet by a heating method comprising; heating said sheet to between about 135? C. to about 150? C. for between about 30 to 45 minutes to obtain a substantially cross-linked foam material with limited volumetric expansion, heating said sheet to between about 160? C. to about 185? C. for between about 90 to about 150 minutes to obtain a substantial volumetric expansion, wherein a bio-based foam block is formed; crushing said bio-based foam block through a multiple compression roller process comprising; crushing said bio-based foam block between compression rollers at least about 4 times, to release a substantial volume of air from inside said bio-based foam block, wherein an open cell foam block is formed; cutting said open cell foam block into sheets; shaping said bio-based open cell foam sheets into pad portions, said pad portions formed within a mold into a shape having an inner surface substantially concave in shape and an outer surface substantially convex in shape.

11. The method of claim 10, wherein said bio-based EVA and PE is also combined with an olefin block copolymer.

12. The method of claim 10, wherein said bio-based foam material is comprised of at least about 40% to about 85% bio-based EVA formed substantially from sugar cane-based ethylene.

13. The method of claim 12, wherein the bio-based EVA is combined with an olefin block copolymer.

14. The method of claim 10, wherein following the compression roller process said foam block is heated to between about 165? C. to about 175? C. for between about 40 to about 50 minutes to substantially restore the thickness of said foam block.

15. The method of claim 10, wherein said pad portion having a Shore 00 hardness value of at least about 25 to about 65.

16. The method of claim 10, wherein said pad portion is comprised of a bio-based carbon content of between about 50% to about 90%.

17. The method of claim 10, wherein said pad portion is formed by a molding method comprising; heating said bio-based open cell foam sheets within a mold to between about 70? C. to about 120? C. for a first press of between about 80 to about 140 seconds in duration, re-heating said bio-based foam sheets within said mold to between about 20? C. to about 60? C. for a second press of between about 60 to about 120 seconds in duration, and cooling said bio-based foam sheets within said mold to about room temperature for between about 30 seconds to about 70 seconds in duration; wherein said partial pad portion is formed within said mold into a shape having an inner surface substantially concave in shape and an outer surface substantially convex in shape.

18. A bra garment, comprising: first and second cup portions that are formed of one or more recycled flexible materials; first and second side wing panels extending from the first and second cup portions, respectively, the first and second side wing panels being formed of one or more recycled flexible materials; and first and second cushioning support pads configured to be coupled with the first and second cup portions, respectively, each of said pads having front and back surfaces, the front surface of each pad having a generally convex shape and the back surface of each pad having a generally concave shape; each of said pads being formed of a bio-based open cell foam material that has hardness and density values that provide both cushioning and support to breasts of a wearer of the bra garment; said bio-based open cell foam material comprising at least about 60-85% bio-based EVA and bio-based PE mixture formed substantially from sugar cane-based ethylene; said bio-based EVA and PE mixture combined with at least; a peroxide-based initiator, and a foaming agent; said bio-based EVA, bio-based PE, peroxide-based initiator and foaming agent mixture formed into a substantially flat sheet by methods comprising; the addition of heat to a temperature of between about 105? C. to about 130? C. to form a melt mixture, extruding said melt mixture to form said mixture into a shape, maintaining said shape during extrusion at a temperature of between at least about 60? C. to about 90? C., and compressing said shape to form a substantially flat sheet; expanding the volume of said substantially flat sheet by a heating method comprising; heating said sheet to between about 135? C. to about 150? C. for between about 30 to 45 minutes to obtain a substantially cross-linked foam material with limited volumetric expansion, heating said sheet to between about 160? C. to about 185? C. for between about 90 to about 150 minutes to obtain a substantial volumetric expansion, wherein a bio-based foam block is formed; crushing said bio-based foam block through a multiple compression roller process comprising; crushing said bio-based foam block between compression rollers at least about 4 times, to release a substantial volume of air from inside said bio-based foam block, wherein an open cell foam block is formed; cutting said open cell foam block into sheets; shaping said bio-based open cell foam sheets into pad portions, said pad portion formed within a mold into a shape having an inner surface substantially concave in shape and an outer surface substantially convex in shape.

19. The bra garment of claim 18, wherein said bio-based EVA and PE is also combined with an olefin block copolymer.

20. The bra garment of claim 18, wherein said bio-based foam material is comprised of at least about 40% to about 85% bio-based EVA formed substantially from sugar cane-based ethylene.

21. The bra garment of claim 20, wherein the bio-based EVA is combined with an olefin block copolymer.

22. The bra garment of claim 18, wherein following the compression roller process said foam block is heated to between about 165? C. to about 175? C. for between about 40 to about 50 minutes to substantially restore the thickness of said foam block.

23. The bra garment of claim 18, wherein said first and second cushioning support pads having a Shore 00 hardness value of at least about 20 to about 70.

24. The bra garment of claim 18, wherein said first and second cushioning support pads are comprised of a bio-based carbon content of between about 40% to about 90%.

25. The bra garment of claim 18, wherein the said sheet formed by said cutting method is comprised of an open cell foam having a density in the range of about 0.020 to about 0.045 g/cm3.

26. A method for making a bio-based open-cell foam block for use in manufacturing cushioning support pads for a bra garment or other garment, comprising; one or more bio-based foam materials, comprising at least about 40-85% bio-based EVA and bio-based PE formed substantially from sugar cane-based ethylene; said bio-based EVA and PE combined with at least; a peroxide-based initiator, and a foaming agent; said bio-based EVA, bio-based PE, peroxide-based initiator and foaming agent mixture formed into a substantially flat sheet by methods comprising; the addition of heat to a temperature of between about 105? C. to about 130? C. to form a melt mixture, extruding said melt mixture to form said mixture into a shape, maintaining said shape during extrusion at a temperature of between at least about 60? C. to about 90? C., and compressing said shape to form a substantially flat sheet; expanding the volume of said substantially flat sheet by a heating method comprising; heating said sheet to between about 135? C. to about 150? C. for between about 30 to 45 minutes to obtain a substantially cross-linked foam material with limited volumetric expansion, heating said sheet to about 160? C. to about 185? C. for between about 90 to about 150 minutes to obtain a substantial volumetric expansion, wherein a bio-based foam block is formed; crushing said bio-based foam block through a multiple compression roller process comprising; crushing said bio-based foam block between compression rollers at least about 4 times, to release a substantial volume of air from inside said bio-based foam block, wherein an open cell foam block is formed.

27. The method of claim 26, wherein following the compression roller process said foam block is heated to between about 165? C. to about 175? C. for between about 40 to about 50 minutes to substantially restore the thickness of said foam block.

28. The method of claim 26, wherein said bio-based EVA and PE is also combined with an olefin block copolymer.

29. The method of claim 26, wherein said bio-based foam material is comprised of at least about 40% to about 85% bio-based EVA formed substantially from sugar cane-based ethylene.

30. The method of claim 29, wherein said bio-based EVA is also combined with an olefin block copolymer.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) The accompanying drawings are incorporated in and constitute a part of this specification. It is to be understood that the drawings illustrate only some examples of the disclosure and other examples or combinations of various examples that are not specifically illustrated in the figures may still fall within the scope of this disclosure. Examples will now be described with additional detail through the use of the drawings, in which:

(2) FIG. 1 is a front or outside elevational view of an exemplary sustainable bra garment, according to present disclosure;

(3) FIG. 2 is a rear or inside elevational view of the sustainable bra garment illustrated in FIG. 1;

(4) FIG. 3 is a front or outside elevational view of another exemplary sustainable bra garment, according to present disclosure;

(5) FIG. 4 is a rear or inside elevational view of the sustainable bra garment illustrated in FIG. 3; and

(6) FIG. 5 is an enlarged partial cross-sectional view of a cup of the sustainable bra garment according to the present disclosure.

(7) FIG. 6a is a side perspective view of a melt mixture for the bio-based foam material during a single screw extrusion step to form the mixture into a shape.

(8) FIG. 6b is a perspective view of a foam block (or bun) of the bio-based foam material before being subjected to multiple crushing steps through a compression roller process to transition the foam to an open cell structure.

(9) FIG. 6c is a perspective view of a foam block (bun) of the bio-based foam material after heating in an oven to restore the foam block's thickness subsequent to the crushing process.

(10) FIG. 6d is a front perspective view of a bio-based open cell foam sheet used for forming one or more pads made in accordance with the present disclosure.

(11) FIG. 7 is a front perspective view of pad portions partially formed from a bio-based open cell foam sheet, as illustrated in FIG. 6, made in accordance with the present disclosure.

(12) FIG. 8 is a front or elevational view of a finished pad made according to the present disclosure.

DETAILED DESCRIPTION

(13) Referring to the figures, the present disclosure generally relates to a bra garment 100 formed of sustainable and recycled materials that is environmentally friendly, non-toxic to the wearer to promote health and wellness. The bra garment 100 may be, for example a bra, sports bra, a maternity bra, a brassier, a bikini top, a camisole, other lingerie top, or other breast covering garment, such as swimwear.

(14) The bra garment 100 may generally comprise cup portions 102a, 102b, side wing panels 104a, 104b extending from the respective cup portions 102a, 102b, and pads 108 for the cup portions 102a, 102b. Shoulder straps 106a, 106b may also be provided such that shoulder strap 106a connects between cup portion 102a and side wing panel 104a and shoulder strap 106b connects between cup portion 102b and side wing panel 104b. The pads 108 are formed of a bio-based material that provides both cushioning and support for a wearer's breasts. The remainder of the bra garment 100 may be formed of recycled materials and/or sustainable materials. As such, the entirety or substantially the entirety of the bra garment 100 can be formed of only sustainable bio-based and recycled materials.

(15) The sustainable material in accordance with the present disclosure is a Bio-Based Open Cell Foam material that is non-toxic to the wearer and may also be devoid of fossil-fuel-based foam material and the like. The sustainable material used to form the pads 108, for example, can have hardness and density values sufficient to provide both cushioning and support to the wearer. And the sustainable material for the bra garment 100 can be manufactured by a sustainable and environment-friendly process.

(16) The bio-based material in accordance with the present disclosure is one that is ecological, friendly, climate-friendly, green, environmental, environmentally-sound, fuel-efficient, energy-efficient, non-polluting, organic, and energy-saving. The bio-based material is a material that can be viable, continuous, continual, feasible, unceasing, livable, supportable, imperishable, unending, renewable, and green. A bio-based material is produced based on available resources to meet current needs while ensuring that adequate resources are available for future generations. In an example, the bio-based material can be a sugar cane, soy bean or corn-based polymer. Also, biodegradable additives can be added to the foam.

(17) The cup portions 102a and 102b and the side wing panels 104a and 104b may be formed of a recycled material, such as a recycled fabric. A recycled material in accordance with the present disclosure is one that is waste converted into usable material. Recycled fabrics are waste products or fabrics and textiles that can be sorted, graded and reused again to make recycled fabrics, such synthetic fibers like polyester, nylon, and the like.

(18) Each of the cup portions 102a, 102b of the bra garment 100 has an outer piece 120 and an inner piece 122 that can be attached, such as by sewing, to one another at respective perimeters thereof forming a pad receiving area 124 therebetween in which respective pads 108 are contained, as seen in FIG. 5. The outer piece 120 may have a generally convex shape selected from a number of available breast cup sizes. The inner piece may have a generally concave shape selected from a number of available cup sizes. The outer and inner pieces 120 and 122 are formed of one or more flexible materials. In an example, the outer piece can be formed of nylon or recycled nylon and the inner piece can be formed of polyester or recycled polyester. The polyester can be brushed for added softness against the wearer's skin.

(19) Each of the pads 108 has front and back surfaces 110 and 112 that correspond to the outer and inner pieces 120 and 122, respectively, of the cup portions 102a, 102b. The front surface 110 of each pad 108 has a generally convex shape and the back surface 112 of each pad 108 has a generally concave shape, as best seen in FIG. 5. The size of the pad 108 can be any breast cup size and generally corresponds to the size of the outer and inner pieces 120 and 122 of the cup portions 102a, 120b.

(20) Each of the pads 108 is formed of a sustainable material that is a Bio-Based Open Cell Foam material with hardness, bounce back and density values that provide both cushioning and support to breasts of a wearer of the sustainable bra garment, and that is non-toxic to the wearer. For example, the bio-based material of the pads 108 may be comprised of between about 40% to 85% Bio-Based EVA and PE Open Cell Foam or between about 40% to 85% EVA Open Cell Foam. This ratio of bio-based material provides the desired flexibility to the pads 108 as well as providing comfort and cushioning and sufficient support to the wearer.

(21) The Open Cell Foams used for the pads 108 of the present invention, are produced by a multi-step process of mixture, extrusion, sheeting, and molding from a bio-based resin compound that may be formulated using a number of raw ingredients including, substantially Bio-Based EVA alone or a combination of Bio-Based EVA and PE as the resin base, as well as additives which act as catalysts to increase production speed and blowing agents to create gas bubbles during foam formulation. The physical properties of Bio-Based Open Cell Foams are dependent on its composition and reaction temperature at the production stage.

(22) As a more specific example of a preferred embodiment according to the present invention, the pads 108 are formed of a bio-based material that use between 25% to 85% bio-based EVA and 5 to 45% Bio-Based Polyethylene (PE), both of which are comprised of substantially sugar cane-based ethanol that is converted into ethylene. A smaller percentage of an olefin block copolymer, such as Dow Infuse 9107 Olefin Block Copolymer, can be also mixed with the Bio-Based EVA and PE, which assists in controlling shrinkage and improves the elastic recovery of the resulting Bio-Based Open Cell Foam. The Bio-Based EVA (bio-based ethylene from sugarcane and vinyl acetate) is mixed together with the Bio-Based PE and olefin block copolymer, and then combined with an initiator, such as a hydrogen peroxide (or bis peroxide) and a blowing (or foaming) agent, such as an azodicarbonamide, as well as other chemicals and additives known in the art, such as a titanium dioxide which may be used as a white coloring pigment. A preferred formulation of the Bio-Based EVA and PE combination, together with other referenced components, used to form the pads 108 of the present invention is shown in the table below:

(23) TABLE-US-00001 Raw Material PHR % g SVT2180 (Bio-Based EVA) 65.53 48.53 486 SEB853 (Bio-Based PE) 34.47 25.53 255 CaCO3 (LS-625) 17.55 13.00 130 Zinc Oxide 2.03 1.50 15 Stearic Acid 1.12 0.83 8 ADCA (AC-3000F) 13.50 10.00 100 DCP 99% (BIS) 0.82 0.61 6 Total 135.03 100.00 1000 *PHR- is an acronym for per hundred parts resin

(24) A preferred formulation of the Bio-Based EVA and PE combination, together with an olefin block copolymer and other referenced components, used to form the pads 108 of the present invention is shown in the table below:

(25) TABLE-US-00002 Raw Material PHR* % g SVT2180 (Bio-Based EVA) 58.06 43.00 430 SEB853 (Bio-Based PE) 27.01 20.00 200 Infuse 9107 (Olefin Block Copolymer) 14.93 11.06 111 CaCO3 (LS-625) 17.55 13.00 130 Zinc Oxide 2.03 1.50 15 Stearic Acid 1.12 0.83 8 ADCA (AC-3000F) 13.50 10.00 100 DCP 99% (BIS) 0.82 0.61 6 Total 135.03 100.00 1000 *PHR- is an acronym for per hundred parts resin

(26) Additional formulations for preferred embodiments according to the present invention may be used to form the pads 108 with a bio-based material having only bio-based EVA comprised of substantially sugar cane-based ethanol that is converted into ethylene. A preferred formulation of the Bio-Based EVA material, together with the other referenced components, used to form the pads 108 of the present invention is shown in the table below:

(27) TABLE-US-00003 Raw Material PHR % g SVT2180 (Bio-Based EVA) 100 75.67 757 CaCO3 (LS-625) 16 12.11 121 Zinc Oxide 2.0 1.51 15 Stearic Acid 1.0 0.76 7.6 ADCA (AC-3000F) 12.3 9.3 93 DCP 99% (BIS) 0.85 0.64 6.4 Total 132.15 100.00 1000

(28) The bio-based material having only bio-based EVA may also be combined with an olefin block copolymer, such as Dow Infuse 9107 Olefin Block Copolymer. A preferred formulation of the Bio-Based EVA material, together with an olefin block copolymer and other referenced components, used to form the pads 108 of the present invention is also shown in the table below:

(29) TABLE-US-00004 Raw Material PHR % g SVT2180 (Bio-Based EVA) 85 63.26 632.6 Infuse 9107 (Olefin Block Copolymer) 15 11.16 111.6 CaCO3 (LS-625) 18 13.4 134 Zinc Oxide 2.0 1.49 15 Stearic Acid 1.0 0.74 7.4 ADCA (AC-3000F) 12.5 9.3 93 DCP 99% (BIS) 0.86 0.64 6.4 Total 132.15 100.00 1000

(30) A preferred method to form the Bio-Based Open Cell Foam used for the pads 108 of the present invention includes, heating the Bio-Based EVA/PE formulation from room temperature to a temperature of between about 105? C. (221? F.) to about 130? C. (about 266? F.) to create a melt mixture that resembles the consistency of a dough. Such a mixture is then extruded in a single screw extruder. The preferred extrusion temperature can range from between about 80? C. (about 176? F.) to about 90? C. (about 194? F.) to form the mixture into a shape 113 as shown in FIG. 6a. This shape 113 should preferably be kept (during the remainder of the extrusion process) at temperatures of between about 60? C. (about 140? F.) to about 90? C. (about 194? F.) to maintain the extruded shape, after which the shape is compressed using a pass-through pressing belt to form a substantially flat sheet. The volumetric shape of the substantially flat sheet is then expanded through a two-step heating process comprising: 1) heating said sheet to a temperature of between about 135? C. (about 275? F.) to about 150? C. (about 300? F.) for a duration of between about 30 to 45 minutes to obtain a substantially cross-linked foam material, preferably a 100% crosslinked ratio, with limited to moderate volumetric expansion, and 2) heating said sheet to between about 160? C. (about 320? F.) to about 185? C. (about 365? F.) for a duration of between about 90 to about 150 minutes to obtain a substantial volumetric expansion. The volumetric expansion of the foam shape can be as much as about 36-38 times of the original shape to form a foam sheet. Following the second heating process, the Bio-Based foam sheet is preferably subjected to a cooling process within the mold. A preferred cooling process may use cold water at about 15? Celsius (about 59? F.) for a duration of between about 70 to 90 minutes. After the completion of the second (heating) step of the two-step process, a block 114a with preferred dimensions of about 2.4 meter in length, 1 meter wide and 90 mm in thickness will result.

(31) The foam block (or bun) 114a is preferably kept at room temperature for about 24 hours before being subjected to multiple crushing steps through a compression roller process as shown in FIG. 6b, to obtain an open cell structure within the foam block 114a. A preferred compression roller process is performed by passing the foam block 114a through a compression roller machine for about two back and forth cycles, such that the foam block 114a is crushed between the rollers at least about 4 times, to release as much air from inside the foam as possible. The foam block may also be subsequently heated in an oven at a temperature of between about 165? to 175? C. for 40 to 50 minutes, which serves to restore the foam block's thickness and results in an open cell foam block 114b as shown in FIG. 6c after the crushing process.

(32) The open cell foam block is thereafter cut or sliced into thinner sheets, preferably ranging in thickness from about 4 mm to about 13 mm. An example of a resulting bio-based open cell foam sheet of the present invention 115 is shown in FIG. 6d, which can be used as material for forming one or more pads 108.

(33) The foam sheets 115 have a range of hardness, measured on an ASTM D2240 standard, from about 3 to about 50 on a Shore 00 scale and a preferable hardness from about 6 to 25 on a Shore 00 scale.

(34) It was also determined that the density of a foam sheet 115 is in the range of about 0.020 to about 0.045 g/cm3, with a preferred density range of about 0.025 to about 0.035 g/cm3 using an ISO 845 test standard as a preferred method. The ISO 845 test standard is commonly used to describe the determination of the specific gravity (relative density) and density of samples of solid plastics in forms such as sheets, rods, tubes, or molded items such as the open cell foam sheets 115 described herein (FIG. 6d).

(35) The bio-based foam sheet 115 may thereafter be laminated with fabrics such as polyester, polyamide, nylon, polyester and nylon blend, and the like. An example of a preferred fabric is 100% polyester, Double-sided 72D superfine brushed fabric. In a preferred lamination process, an adhesive glue is used to affix the fabric to the foam sheet, such as an NEL-1018 hot melt polyurethane adhesive with a preferred viscosity of 10,000 (?2,000 cps (centipoise)/100? C. A preferred glue quantity is 25 grams per square meter of foam sheet with a fabric lamination temperature of 95? C. The duration of the lamination process to completion, including the setting and drying of the laminated foam sheet is preferably about 24 hours.

(36) The Bio-Based Open Cell Foam sheet 115 is then formed into partial pad portions 115a and 115b (FIG. 7). A preferred molding method to form a standard cushioning cup portion comprises: 1) heating a portion of said Bio-Based Open Cell Foam sheet within a mold to between about 70? C. (160? F.) to about 120? C. (248? F.) for a first press of between about 80 to about 160 seconds in duration, and thereafter 2) heating said Bio-Based Open Cell Foam sheet within said mold to between about 20? C. (68? F.) to about 60? C. (140? F.) for a second press of between about 60 seconds to about 120 seconds in duration, and 3) cooling in a press the said Bio-Based Open Cell Foam at room temperature for between about 30 seconds to about 70 seconds in duration; such that each said partial pad portion (115a and 115b) is formed within said mold into a shape having an inner surface substantially concave in shape and an outer surface substantially convex in shape and resulting in pad portions having hardness values of between about 20 to about 70 on a Shore 00 scale and preferred hardness values of between about 35 to about 55 on a Shore 00 scale. Examples of partially formed pad portions 115a and 115b are shown in process in FIG. 7 after forming of the pad cup portions using the above preferred molding methods.

(37) An example of a finished pad portion 108 made in accordance with the above processing methods is shown in FIG. 8. In addition to the above-preferred molding methods, several molding method time and temperature variations can be employed to yield pad portions having various cup sizes and styles, such as the various methods for making multiple styles in the table disclosed below:

(38) TABLE-US-00005 Molding Conditions 1st press 1st press 2nd press 2nd press 3rd press 3rd press temperature time temperature time temperature time Style (? C.) (seconds) (? C.) (seconds) (? C.) (seconds) T-Shirt Pad 90-100 100 Room 100 Not Not temperature Applicable Applicable Balconette 90-100 200 Room 100 Not Not Pad temperature Applicable Applicable Push-Up Pad 90-100 200 Room 130 Room 50 temperature temperature

(39) Several such pad portion samples were subjected to an ASTM test method to assess a preferred range of pad material hardness properties. The material hardness of each sample ranging from cup sizes of 32A to 44G (United States of America standard sizes) was determined at various surface points by subjecting samples to a standard ASTM D2240 test method using a durometer having a Shore 00 scale to measure the material hardness. It was determined after such hardness testing that a range of Shore 00 hardness values of between about 20 to about 70 was observed, with a resulting preferred Shore 00 material hardness range of between about 35 to about 55, to provide both appropriate cushioning and sufficient support for the breasts of a wearer of a sustainable bra garment or other garment in which such pads 108 are incorporated.

(40) It has been determined that a Bio-Based carbon content of 77% can be achieved in samples of a finished pad portion 108. The Bio-Based carbon content of finished pad portion samples was determined through a standard ASTM D6866 (Method B) analysis which indicates a percentage carbon from natural (plant or animal by-product) sources versus synthetic (petrochemical) sources. For reference, 100% Biobased Carbon indicates that a material is entirely sourced from plants or animal by-products and 0% Biobased Carbon indicates that a material did not contain any carbon from plants or animal by-products. A value in between represents a mixture of natural and fossil fuel sources, as was found in the finished pad portions 108 described herein.

(41) The front surface 110 of each pad 108 may also be laminated to assist with application of the outer piece 120 of the cup portions 102a, 120b. The back surface 112 of each pad 108 may be devoid of any lamination. Alternatively, each pad 108 can be devoid of any lamination altogether, i.e. on either the front or back surface 110 and 112 thereof.

(42) Each of the side wing panels 104a, 104b is connected to an outer edge of a respective cup portion 102a, 102b. The side wing panels 104a, 104b can be formed of one or more fabrics, such as nylon, recycled nylon and the like. The side wing panels 104a, 104b can be made of the same or different recycled fabric as that of the cup portions 102a, 102b. Also, recycled yarns may be used for sewing the perimeters of any of the portions or panels of the bra garment 100, such as the perimeters 109 around the side wing panel 104a, 104b. The free ends of the side wings panels 104a, 104b include corresponding clasp elements 130 and 132, respectively, such as hook and eye elements, for clasping the free ends together in a conventional manner. The clasp elements 130 and 132 may be formed of recycled materials, such as recycled metal for the hook, and fabric or yarn for the eye.

(43) The shoulder straps 106a, 106b may be formed of recycled materials, such as a recycled elastic material, such as recycled yarns and the like, to provide flexibility and comfort to the wearer. Each shoulder strap 106a and 106b may be adjustable using adjustable elements such as corresponding ring and hook members 134 and 136, which function as is known in the art. The ring and hook members 134 and 136 may be formed of a sustainable material, such as a sugar cane polymer. The sugar cane polymer of the ring and hook members 134 and 136 would be harder and more rigid that the sugar cane polymer which forms the pads 108. That is, the sugar cane polymer of the ring and hook members 134 and 136 have a sufficient hardness value and rigidity to couple to the shoulder straps 106a, and 106b to allow adjustment thereof.

(44) The bra garment 100 may include an underwire, as seen in FIGS. 1 and 2, or the bra garment 100 may not have underwire, as seen in FIGS. 3 and 4. The bra garment 100 has an underwire channels 140a, 140b at the bottom of supports 102a, 102b, respectively. The underwire channels 140a, 104b may be formed of recycled fabrics, such as recycled yarns, and are sized to receive a conventional underwire. A bridge panel 138 extends between the underwire channels 140a, 140b to join the cup portions 102a, 102b. The bridge panel 138 can be formed of a recycled material, such as recycled nylon.

(45) The bra garment 100 as seen in FIGS. 3 and 4, is substantially the same as the bra garment 100 of FIGS. 1 and 2, except that it does not have an underwire or underwire channels. The cup portions 102a, 102b of the bra garment 100 are the same as cup portion 102a, 102b, except that the cup portions 102a, 102b are sewn together, using recycled yarn for example, at a center line 150 and a bottom line 152, as best seen in FIG. 4. An optional lace trim 154 may be provide at the top of the cup portions 102a, 120b. The lace trim 154 can be formed of a recycled material, such as recycled yarn and the like.

(46) It will be apparent to those skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings that modifications, combinations, sub-combinations, and variations can be made without departing from the spirit or scope of this disclosure. Likewise, the various examples described may be used individually or in combination with other examples. Those skilled in the art will appreciate various combinations of examples not specifically described or illustrated herein that are still within the scope of this disclosure. In this respect, it is to be understood that the disclosure is not limited to the specific examples set forth and the examples of the disclosure are intended to be illustrative, not limiting.

(47) The following definitions and terms are used in this disclosure:

(48) EVA: As used in this disclosure, EVA is an acronym known and used in the art as a reference to_ethylene-vinyl-acetate, an elastic petroleum-based polymer that can be used to produce materials and products with a rubber-like softness and flexibility.

(49) Bio-Based EVA: As used in this disclosure, Bio-Based EVA is used to describe a carbon negative material made substantially from sugarcane (sugarcane ethanol) and used as an alternative and/or substitute for petroleum-based EVA polymers. Existing bio-based EVA materials are available commercially and are supplied by Braskem as an EVA resin. Preferred resins are identified as EVA Evance SVT2145 and SVT2180, which are typically in the form of pellets and processed to obtain foam sheets for use in the soles of footwear products, or in toys and furniture.

(50) Polyethylene (PE): As used in this disclosure, Polyethylene or PE is used to describe a synthetic resin made from the polymerization of ethylene. Polyethylene is a member of an important family of polyolefin resins and is one of the most widely used plastics world-wide, being made into products ranging from clear food wrap and shopping bags to detergent bottles and automobile fuel tanks. It can also be slit or spun into synthetic fibers or modified to take on the elastic properties of a rubber.

(51) Bio-Based PE: As used in this disclosure, Bio-Based PE is used to describe a synthetic resin of polyethylene having a high proportion of renewable raw materials such as sugar cane as the starting material

(52) Open Cell Foam: As used in this disclosure, Open Cell Foam is used to describe a foam material comprised of a series of inter-connecting cells with an open structure, which enhance the elastic properties of the cells. When compressed, cells collapse together tightly in any direction, and when compression is released, the air intake allows the padding to return to its original state quickly. Open cells are less likely to be broken, resulting in superior performance when used overtime. Open cells are typically less dense than closed cell foams, although depending on the application, the composition of the padding can be altered to increase density.

(53) Closed Cell Foam: As used in this disclosure, Closed Cell Foam is made up of a series of enclosed air pockets, comparable to small balloons or rubber balls compacted within a rubber membrane. When compressed, air is released through the cell walls and the air pockets are squashed down to small disc shapes. When compression is released, air enters back through the cell walls at a slower rate than open cells. Closed cells tend to be stiffer or more rigid due to this giving them superior resistance to moisture, ideal for use in damp applications such as gasketing and insulation. Similar to open cell padding, closed cell composition can be altered to amend its density, rigidity, compression resistance and other properties.

(54) Hydrogen peroxide or bis (trifluormethyl) peroxide: As used in this disclosure, hydrogen peroxide or bis peroxide is used to describe a chemical used as an initiator (or catalyst) for unsaturated ethylene-like molecules in the production of stable polymeric materials, including as an initiator for Bio-Based EVA and PE to yield a cross-linked Open Cell Foam having enhanced mechanical properties. Examples of appropriate cross-linking peroxides for open cell foams are Perkadox? BC-FF (Nouryon) and Luperox? 802 (Arkema).

(55) Blowing or Foaming Agent: As used in this disclosure, a blowing agent or foaming agent is used to describe chemical compositions used in state-of-the-art polymerization processes, typically an azodicarbonamide, capable of producing a cellular structure through a foaming process to reduce density and increase relative stiffness of a base polymer. It has also been determined that more eco-friendly compositions, such as sodium bicarbonate (Alve-One? commercially available from Solvay), may also be used as effective blowing or foaming agents to form Bio-Based EVA and PE Open Cell Foams. Another example of an appropriate and commercially available foaming agent is Hydrocerol (Avient).

(56) Zinc OxideAs used in this disclosure zinc oxide is used to describe what is known in the art as a kicker, which is typically added to the formulation to assist with heat flow distribution inside of the foam and to decrease the temperature of the blowing or foaming agent, such as an azodicarbonamide, during the blowing or foaming process.

(57) Titanium dioxide or titanium IV oxide [TiO2]As used in this disclosure, titanium dioxide or titanium IV oxide is used to describe a substance typically used as a pigment (also known as titanium white) for paints and polymers.

(58) Shore Hardness/Asker HardnessAs used in this disclosure, Shore Hardness and Asker Hardness are terms used to describe the measure of hardness of a given material (or how resistant it will be to permanent indentation), measured by the depth of indentation that is created on the material with a specified force. The measuring instrument typically used is known as a durometer, and different respective scales for measuring hardness (such as Asker, Shore, Rockwell hardness scales) are known in the art. Accordingly, different hardness scales are used for measuring the solidity of different materials with varying properties, like rubbers, polymers and elastomers. The most commonly used scales for measuring the hardness of rubber materials are the Asker C and Shore 00 or A scales for softer materials and the Shore D scale for harder materials. The Asker C, Asker F and Shore 00 scales are generally used for measuring hardness of more flexible foam or rubber materials.

(59) As used in this specification and the appended claims, the singular forms a, an and the include plural referents, unless the context clearly dictates otherwise. Similarly, the adjective another, when used to introduce an element, is intended to mean one or more elements. The terms comprising, including, having and similar terms are intended to be inclusive such that there may be additional elements other than the listed elements.

(60) Additionally, where a method described above does not explicitly require an order to be followed by its steps or an order is otherwise not required based on the description or claim language, it is not intended that any particular order be inferred. Likewise, where a method claim below does not explicitly recite a step mentioned in the description above, it should not be assumed that the step is required by the claim.

(61) It is noted that the description and claims may use geometric or relational terms. These terms are not intended to limit the disclosure and, in general, are used for convenience to facilitate the description based on the examples shown in the figures. In addition, the geometric or relational terms may not be exact. For instance, walls may not be exactly perpendicular or parallel to one another because of, for example, roughness of surfaces, tolerances allowed in manufacturing, etc., but may still be considered to be perpendicular or parallel.