Fire-retardant mattress core cap and manufacturing method thereof
阅读说明:本技术 阻燃床垫芯帽及其制造方法 (Fire-retardant mattress core cap and manufacturing method thereof ) 是由 C·K·马丁 P·隆格 于 2020-06-22 设计创作,主要内容包括:通过以下方法制造织物:提供具有阻燃纤维的非织造絮垫,使用弹性纱线缝编非织造絮垫和热处理经缝编的非织造絮垫。经缝编的非织造絮垫被暴露于65℃至200℃的温度持续30秒至120秒的时间段,并且在机器方向上收缩5%至65%和在横向方向上收缩20%至70%。在实施方案中,织物适于用作床垫芯罩。(The fabric was made by the following method: a nonwoven batt having flame resistant fibers is provided, the nonwoven batt being stitch-bonded using elastic yarns and the stitch-bonded nonwoven batt being heat treated. The stitchbonded nonwoven batt is exposed to a temperature of 65 ℃ to 200 ℃ for a period of 30 seconds to 120 seconds and shrinks by 5% to 65% in the machine direction and 20% to 70% in the cross direction. In embodiments, the fabric is suitable for use as a mattress core cover.)
1. A method of making a fabric comprising the steps of:
providing a nonwoven batt of flame retardant fibers, the nonwoven batt having a machine direction and a cross direction;
stitching the nonwoven batt with an elastic yarn; and
heat treating the stitchbonded nonwoven batt by exposing the stitchbonded nonwoven batt to a temperature of from 65 ℃ to 200 ℃ for a period of from 30 seconds to 120 seconds and allowing the elastic yarns and the nonwoven batt to shrink,
wherein the warp stitched nonwoven batt shrinks by 5% to 65% in the machine direction and by 20% to 70% in the cross direction.
2. The method of claim 1, wherein the flame retardant fibers comprise flame retardant rayon.
3. The method of claim 1, wherein the flame resistant fibers comprise polyaramid.
4. The method of claim 3, wherein the flame retardant fiber is a blend of inherently flame retardant cellulosic fibers and polyaramid fibers.
5. The method of claim 4 in which the blend of inherently flame resistant cellulosic fibers and polyaramid fibers is 1 to 30 weight percent of the total weight of the nonwoven batt.
6. The method of claim 4, wherein the flame retardant fibers comprise polyester fibers.
7. The process of claim 6 wherein the polyester fiber is 1% to 20% of the total weight of the nonwoven batt.
8. The method of claim 6, wherein the flame retardant fibers comprise modacrylic fibers.
9. The method of claim 8 wherein the modacrylic fiber is from 1 percent to 50 percent of the total weight of the nonwoven batt.
10. The process of claim 1 wherein the density of the flame retardant fibers of the nonwoven batt is from 1.5 denier to 7 denier.
11. The method of claim 1 wherein the nonwoven batt is 60 to 90 weight percent of the total weight of the fabric.
12. The method of claim 1, wherein the elastic yarn comprises a filament polyester.
13. The method of claim 1, wherein the elastic yarn has a density of 75 denier to 300 denier.
14. The method of claim 11, wherein the elastic yarn is 10 to 40 weight percent of the total weight of the fabric.
15. The method of claim 1 wherein the step of stitching the nonwoven batt comprises creating stitches using the elastic yarns, and wherein the stitches have a pitch of 10 to 28 yarns per inch.
16. The method of claim 1, wherein the fabric has a weight of 50 grams per square meter (gsm) to 400 grams per square meter (gsm).
17. The method of claim 1 further comprising the step of coating the heat treated, stitchbonded nonwoven fabric with a coating.
18. The method of claim 17, wherein the coating comprises a nanoclay.
19. The method of claim 1, wherein the fabric is suitable for use as a mattress core cover.
20. A method of making a fabric comprising the steps of:
providing a batt of flame retardant fibers, the batt having a machine direction and a cross direction;
stitching the batt with yarn; and
heat treating the stitchbonded batt and shrinking the batt, wherein the stitchbonded batt shrinks by 5% to 65% in the machine direction and by 20% to 70% in the cross direction.
21. The method of claim 20 wherein the heat treating step comprises exposing the stitchbonded batt to a temperature of from 65 ℃ to 200 ℃.
22. The method of claim 21 wherein the heat treating step comprises exposing the stitchbonded batt to a temperature for a period of time of 30 seconds to 120 seconds.
23. A method of making a fabric comprising the steps of:
providing a batt of flame retardant fibers, the batt having a machine direction and a cross direction;
stitching the batt with yarn; and
heat treating the stitchbonded batt and shrinking the batt, wherein the stitchbonded batt is shrunk by 5% to 65% in the machine direction.
24. The method of claim 23 wherein the heat treating step comprises exposing the stitchbonded batt to a temperature of from 65 ℃ to 200 ℃.
25. The method of claim 24 wherein the heat treating step comprises exposing the stitchbonded batt to a temperature for a period of time of 30 seconds to 120 seconds.
26. A method of making a fabric comprising the steps of:
providing a batt of flame retardant fibers, the batt having a machine direction and a cross direction;
stitching the batt with yarn; and
heat treating the stitchbonded batt and shrinking the batt, wherein the stitchbonded batt is shrunk by 20% to 70% in the cross direction.
27. The method of claim 26 wherein the heat treating step comprises exposing the stitchbonded batt to a temperature of from 65 ℃ to 200 ℃.
28. The method of claim 27 wherein the heat treating step comprises exposing the stitchbonded batt to a temperature for a period of time of 30 seconds to 120 seconds.
Technical Field
The present invention relates to fireblocking fabrics used in bedding and sleeping products such as mattresses, and more particularly to stretchable and resilient insulating and fireblocking covers (covers) and caps (caps) for mattress cores (mattress cores).
Background
Thousands of residential fires in the united states each year, resulting in hundreds of deaths and billions of dollars in property damage due to mattress and bedding fires. The high value of fire protection has led to the establishment of standards and regulations that reduce the likelihood of such fires occurring. One approach to reducing the likelihood of a residential fire is to use flame resistant fabrics as flame barriers in mattresses and bedding.
Disclosure of Invention
In an embodiment, a method of making a fabric comprises the steps of: providing a non-woven batt of flame retardant fibers, the nonwoven batt having a machine direction (machine direction) and a cross direction; stitchbonded (stitch bond) nonwoven batts using elastic yarns (yarn); heat treating the stitchbonded nonwoven batt by exposing the stitchbonded nonwoven batt to a temperature of from 65 ℃ to 200 ℃ for a period of from 30 seconds to 120 seconds and shrinking the elastic yarns and the nonwoven batt, wherein the stitchbonded nonwoven batt is shrunk by from 5% to 65% in the machine direction and from 20% to 70% in the cross direction.
In embodiments, the flame retardant fiber comprises flame retardant rayon (rayon). In embodiments, the flame resistant fibers comprise polyaramids. In embodiments, the flame retardant fiber is a blend of inherently (atherently) flame retardant cellulosic fibers and aramid fibers. In embodiments, the blend of inherently flame retardant cellulosic fibers and polyaramid fibers is from 1 to 30 weight percent of the total weight of the nonwoven batt. In embodiments, the flame retardant fibers comprise polyester fibers. In embodiments, the polyester fiber is 1% to 20% of the total weight of the nonwoven batt. In embodiments, the flame retardant fibers comprise modacrylic fibers. In embodiments, the modacrylic fiber is from 1% to 50% of the total weight of the nonwoven batt. In embodiments, the flame retardant fibers of the nonwoven batt are from 1.5 denier to 7 denier. In embodiments, the nonwoven batt is from 60 to 90 weight percent of the total weight of the fabric.
In embodiments, the elastic yarn comprises filament (filament) polyester. In embodiments, the elastic yarn has a density of 75 denier to 300 denier. In embodiments, the elastic yarn is 10 to 40 weight percent of the total weight of the fabric. In embodiments, the step of stitching the nonwoven batt comprises creating a stitch (stich) with the elastic yarn, and wherein the stitch pitch is between 10 yarns/inch and 28 yarns/inch. In embodiments, the fabric has a weight of 50 grams per square meter (gsm) to 400 grams per square meter (gsm). In embodiments, the method further comprises the step of coating the heat-treated, stitchbonded nonwoven fabric with a coating. In embodiments, the coating comprises nanoclay (nanoclay). In embodiments, the fabric is suitable for use as a mattress core cover.
In an embodiment, a method of making a fabric comprises the steps of: providing a batt of flame retardant fibers, the batt having a machine direction and a cross direction; stitching the batting with yarn; and heat treating the stitch-bonded batt and shrinking the batt, wherein the stitch-bonded batt shrinks by 5% to 65% in the machine direction and 20% to 70% in the cross direction. In embodiments, the heat treatment step comprises exposing the stitchbonded batt to a temperature of from 65 ℃ to 200 ℃. In embodiments, the heat treatment step comprises exposing the stitchbonded batt to a temperature for a period of time from 30 seconds to 120 seconds.
In an embodiment, a method of making a fabric comprises the steps of: providing a batt of flame retardant fibers, the batt having a machine direction and a cross direction; stitching the batting with yarn; and heat treating the stitchbonded batt and shrinking the batt, wherein the stitchbonded batt is shrunk by 5% to 65% in the machine direction. In embodiments, the heat treatment step comprises exposing the stitchbonded batt to a temperature of from 65 ℃ to 200 ℃. In embodiments, the heat treatment step comprises exposing the stitchbonded batt to a temperature for a period of time from 30 seconds to 120 seconds.
In an embodiment, a method of making a fabric comprises the steps of: providing a batt of flame retardant fibers, the batt having a machine direction and a cross direction; stitching the batting with yarn; and heat treating the stitch-bonded batt and shrinking the batt, wherein the stitch-bonded batt shrinks by 20% to 70% in the cross direction. In embodiments, the heat treatment step comprises exposing the stitchbonded batt to a temperature of from 65 ℃ to 200 ℃. In embodiments, the heat treatment step comprises exposing the stitchbonded batt to a temperature for a period of time from 30 seconds to 120 seconds.
In an exemplary embodiment, the heat-treated flame retardant, thermally insulating nonwoven fabric comprises a nonwoven batt stitch-bonded using elastic yarns comprising elastic fibers (elastane) or a combination of elastic fibers and polyester, wherein the fabric is stretchable and resilient. In some embodiments, the heat-treated flame retardant, thermally insulating nonwoven fabric has a Machine Direction (MD) and a cross-direction (CD), and the fabric is stretchable in both the Machine Direction (MD) and the cross-direction (CD). In some embodiments, the heat-treated flame retardant and insulating nonwoven fabric has been subjected to a heat treatment process during which the elastic yarns shrink such that the fabric shrinks in both the Machine Direction (MD) and Cross Direction (CD) as compared to before the heat treatment process. In embodiments, the heat treated fabric shrinks 5% to 65% of the fabric in the Machine Direction (MD) prior to the heat treatment process, while the heat treated fabric shrinks 20% to 70% in the cross direction.
In some embodiments, the elastic yarn is comprised of elastic fibers or a combination of elastic fibers and polyester.
In some embodiments, the nonwoven batt comprises flame retardant fibers. Suitable flame-retardant fibers are made of flame-retardant rayon, polyaramid (for example)Such as, for example,or) An elastic fiber (e.g.,) Flame retardant polyesters and combinations thereof. Flame-retardant rayon includes inherently flame-retardant cellulosic fibers, such as rayon with incorporated silica and cellulosic fibers with incorporated flame-retardant chemicals (e.g., phosphorus compounds). In some embodiments, the nonwoven batt is comprised of flame retardant rayon.
In an embodiment, a mattress core cap according to the present invention comprises the aforementioned stretchable and resilient flame retardant and thermally insulating nonwoven fabric. In embodiments, mattress core caps according to the present invention are pre-formed to closely fit the top, sides and corners (corner) of a mattress core. In an embodiment, a mattress core cap according to the present invention is pre-formed to be applied to the top of a mattress core and pulled down the sides and corners of the mattress core, the mattress core cap having elastic piping along its edges to hold the mattress core cap around the mattress core. In embodiments, the fabric of a mattress core cap according to the present invention stretches to conform to the shape of the foam core as the core is compressed and relaxed in response to movement of the sleeper.
Drawings
For a more complete understanding of the present invention, reference is made to the following detailed description of exemplary embodiments, which is to be considered in connection with the accompanying drawings, which are for the purpose of illustration and not to scale, and wherein:
fig. 1 is a cross-sectional view of a mattress according to an embodiment, the mattress including a mattress core cap covering a mattress core;
fig. 2 is a schematic orthogonal view of the mattress core of fig. 1, with hidden edges of the mattress core shown in phantom;
FIG. 3 is a schematic top view of a sheet of fabric suitable for being shaped into the mattress core cap of FIG. 1 to cover the mattress core of FIG. 2;
FIG. 4 is a schematic orthogonal view of the mattress core cap of FIG. 1 during the step of fitting the mattress core cap onto the foam mattress core of FIG. 1, with hidden edges of the mattress core shown in phantom;
FIG. 5 is a schematic orthogonal view of the mattress core cap of FIG. 1 showing a mechanism for fitting the mattress core cap over the foam mattress core of FIG. 1 with hidden edges of the mattress core shown in phantom;
fig. 6 is a schematic orthogonal view of the mattress core cap of fig. 1 fitted to the mattress core of fig. 1, with hidden edges of the mattress core and hidden features of the mattress core cap shown in phantom;
fig. 7 is a schematic bottom view of the mattress core and mattress core cap of fig. 6.
FIG. 8 is a schematic perspective view of a flame retardant insulating fabric barrier comprising a sheet of heat treated flame retardant insulating nonwoven fabric formed into a sleeve (sleeve) and in its pre-installation rolled configuration;
FIG. 9 is a schematic perspective view of the flame retardant insulating fabric barrier of FIG. 8 in an unfolded configuration;
FIG. 10 is a schematic perspective view of the flame retardant insulating fabric barrier of FIG. 8 in its partially rolled/unrolled configuration;
FIG. 11 is a schematic perspective view of the flame retardant insulating fabric barrier of FIG. 8 installed on a mattress core and in its partially deployed configuration;
FIG. 12 is a schematic perspective view of the flame retardant insulating fabric barrier of FIG. 11 installed on a mattress core and in its deployed configuration; and
fig. 13 is a schematic view of an embodiment of a fabric.
Detailed Description
In an embodiment, a mattress core cap according to the present invention includes a stretchable and resilient heat-treated flame retardant and insulating nonwoven fabric. In embodiments, the nonwoven fabric does not include glass fibers or other components that break up to form irritating or toxic particles.
In the implementation ofIn one embodiment, the heat-treated flame retardant and insulating nonwoven fabric comprises a nonwoven batt comprising flame retardant fibers and stitch-bonded using elastic yarns. Examples of suitable flame-retardant fibers include, but are not limited to, flame-retardant rayon, polyaramid (e.g.,or
) Elastic fibers (e.g., polyurethane,) Flame retardant polyesters and combinations thereof. As used herein, "flame-retardant rayon" includes inherently flame-retardant cellulosic fibers such as, but not limited to, rayon that is incorporated with silica and cellulosic fibers that are incorporated with flame-retardant chemicals (e.g., phosphorus compounds). In some embodiments, the nonwoven batt is comprised of flame retardant rayon fibers. In some embodiments, the nonwoven batt comprises flame retardant rayon fibers and a fiber of polyamide (e.g.,or) Elastic fibers (e.g., polyurethane,) And a flame retardant polyester.In embodiments, a fabric made of one or more elastomeric materials (e.g., polyurethane or other elastomeric fibers, including for example, but not limited toOr
Such asT400) or a combination of one or more such elastomeric materials with polyester. In embodiments, the heat-treated flame retardant and insulating nonwoven fabric comprises crimped or texturized fibers or yarns such that the fibers are extensible even if the fibrous material is not elastic.In other embodiments of the heat-treated flame retardant and insulating nonwoven fabric, 100 weight percent of the fibers in the nonwoven batt are inherently flame retardant cellulosic fibers. In some exemplary embodiments, at least 40 weight percent of the fibers in the nonwoven batt are flame retardant rayon fibers, the remainder being other flame retardant fibers and/or non-flame retardant fibers, based on the total weight of the nonwoven batt. In other exemplary embodiments, the nonwoven batt is a blend of inherently flame retardant cellulosic fibers with other flame retardant and/or non-flame retardant fibers. Exemplary blends include inherently flame retardant cellulosic fibers with one or more of the following fiber types: polyaramid, polyester, polyurethane or other elastic fibers, acrylic, modified acrylic, non-flame retardant cellulosic fibers (e.g., cotton or bamboo), wool, cashmere or silk. A further exemplary blend includes 0% to 30% by total weight of the fibers of inherently flame resistant cellulosic fibers with one or more polyaramid fibers, 0% to 20% by total weight of the fibers of polyester fibers, and 0% to 50% by total weight of the fibers of modacrylic fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is from 5% to 30% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 5% to 25% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is from 5% to 20% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 5% to 15% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 5% to 10% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 5% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 10% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 15% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 20% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 25% of the total weight of the fibers. In embodiments, the blend of flame retardant cellulosic fibers and one or more polyaramid fibers is 30% of the total weight of the fibers. In embodiments, the polyester fibers are 0% to 20% of the total weight of the fibers. In embodiments, the polyester fibers are 5% to 20% of the total weight of the fibers. In embodiments, the polyester fibers are 10% to 20% of the total weight of the fibers. In embodiments, the polyester fibers are 15% to 20% of the total weight of the fibers. In embodiments, the polyester fibers are 5% to 15% of the total weight of the fibers. In embodiments, the polyester fibers are 5% to 10% of the total weight of the fibers. In embodiments, the polyester fibers are 10% to 15% of the total weight of the fibers. In embodiments, modacrylic fiber is 0% to 50% of the total weight of the fiber. In embodiments, modacrylic fiber is 5% to 50% of the total weight of the fiber. In embodiments, modacrylic fiber is 10% to 50% of the total weight of the fiber. In embodiments, the modacrylic fiber is 15% to 50% of the total weight of the fiber. In embodiments, the modacrylic fiber is 20% to 50% of the total weight of the fiber. In embodiments, modacrylic fiber is 25% to 50% of the total weight of the fiber. In embodiments, modacrylic fiber is 30% to 50% of the total weight of the fiber. In embodiments, the modacrylic fiber is 35% to 50% of the total weight of the fiber. In embodiments, the modacrylic fiber is 40% to 50% of the total weight of the fiber. In embodiments, modacrylic fiber is 45% to 50% of the total weight of the fiber. In embodiments, the modacrylic fiber is 10% to 40% of the total weight of the fiber. In embodiments, the modacrylic fiber is 20% to 40% of the total weight of the fiber. In embodiments, the modacrylic fiber is 30% to 40% of the total weight of the fiber. In embodiments, modacrylic fiber is 10% to 30% of the total weight of the fiber. In embodiments, modacrylic fiber is 20% to 30% of the total weight of the fiber.
In other embodiments of the heat treated nonwoven fabric, the materials of the fibers and blends are selected such that the fabric is stretchable and resilient. In other embodiments, the heat-treated flame retardant and insulating nonwoven fabric is stretched in the Machine Direction (MD) of the fabric. In other embodiments, the heat-treated flame retardant and insulating nonwoven fabric extends in the cross-direction (CD) of the fabric. In other embodiments, the heat-treated flame retardant and insulating nonwoven fabric extends in both the Machine Direction (MD) and the cross-machine direction (CD) of the fabric.
In other embodiments of the heat-treated flame retardant and insulating nonwoven fabric, the fiber density of the nonwoven batt is from 1.5 denier to 7 denier. In embodiments, the fiber density of the nonwoven batt is from 1.5 denier to 6 denier. In embodiments, the fiber density of the nonwoven batt is from 1.5 denier to 5 denier. In embodiments, the fiber density of the nonwoven batt is from 1.5 denier to 4 denier. In embodiments, the fiber density of the nonwoven batt is from 1.5 denier to 3 denier. In embodiments, the fiber density of the nonwoven batt is from 3.5 denier to 5.5 denier. In embodiments, the fiber density of the nonwoven batt is 4 denier to 5 denier.
In embodiments, the nonwoven batt is from 60 to 90 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is 70 to 90 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is from 80 to 90 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is from 60 to 80 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is from 60 to 70 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is from 75 to 85 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is 80 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is 70% by weight of the total weight of the fabric. In embodiments, the nonwoven batt is 60% by weight of the total weight of the fabric. In embodiments, the nonwoven batt is 90 weight percent of the total weight of the fabric.
In embodiments, the heat-treated flame retardant insulating nonwoven fabric does not include any binder or adhesive material, such as a thermoplastic or latex. In an exemplary embodiment of the heat-treated flame retardant and insulating nonwoven fabric, the yarns used in the stitchbonded nonwoven batt have a density of from 75 denier to 300 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 75 denier to 250 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 75 denier to 200 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 75 denier to 150 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 75 denier to 100 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 100 denier to 300 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 150 denier to 300 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 200 denier to 300 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 250 denier to 300 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 100 denier to 200 denier. In embodiments, the yarns used to stitch the nonwoven batt have a density of 150 denier to 200 denier. In embodiments, the yarn used to stitch the nonwoven batt has a density of 75 denier. In embodiments, the yarn used to stitch the nonwoven batt has a density of 100 denier. In embodiments, the yarn used to stitch the nonwoven batt has a density of 150 denier. In embodiments, the yarn used to stitch the nonwoven batt has a density of 200 denier. In embodiments, the yarn used to stitch the nonwoven batt has a density of 250 denier. In embodiments, the yarn used to stitch the nonwoven batt has a density of 300 denier.
In other embodiments of the fabric, the yarn is 10 to 40 weight percent of the total weight of the fabric. In embodiments, the yarn is 10 to 30 weight percent of the total weight of the fabric. In embodiments, the yarn is 10 to 20 weight percent of the total weight of the fabric. In embodiments, the yarn is 10 weight percent of the total weight of the fabric. In embodiments, the yarn is 20 weight percent of the total weight of the fabric. In embodiments, the yarn is 30 weight percent of the total weight of the fabric.
In other embodiments, the stitch pitch in the warp stitched, heat treated flame retardant and thermally insulating nonwoven fabric is from 10 yarns/inch to 28 yarns/inch. In embodiments, the stitch pitch in the warp stitched, heat treated flame retardant and thermally insulating nonwoven fabric is from 15 yarns/inch to 28 yarns/inch. In embodiments, the stitch pitch in the warp stitched, heat treated flame retardant and thermally insulating nonwoven fabric is from 20 yarns/inch to 28 yarns/inch. In embodiments, the stitch pitch in the warp stitched, heat treated flame retardant and thermally insulating nonwoven fabric is from 15 yarns per inch to 20 yarns per inch. In embodiments, the stitch spacing in the warp stitched, heat treated flame retardant and thermally insulating nonwoven fabric is from 15 yarns/inch to 21 yarns/inch. In embodiments, the stitch pitch in the warp stitched, heat treated flame retardant and thermally insulating nonwoven fabric is 15 yarns per inch. In embodiments, the stitch pitch in the warp-stitched, heat treated flame retardant and thermally insulating nonwoven fabric is 18 yarns per inch. In embodiments, the stitch spacing in the warp stitched, heat treated flame retardant and thermally insulating nonwoven fabric is 21 yarns per inch. In embodiments, the stitch pitch in the warp-stitched, heat treated flame retardant and thermally insulating nonwoven fabric is 28 yarns per inch.
In other embodiments of the warp stitched, heat treated flame retardant and insulating nonwoven fabric, the weight of the fabric is from 50gsm to 400 grams per square meter (gsm). In embodiments, the fabric has a weight of 100gsm to 400 grams per square meter (gsm). In embodiments, the fabric has a weight of 200gsm to 400 grams per square meter (gsm). In embodiments, the fabric has a weight of 300gsm to 400 grams per square meter (gsm). In embodiments, the fabric has a weight of 100gsm to 300 grams per square meter (gsm). In embodiments, the fabric has a weight of 100gsm to 200 grams per square meter (gsm). In embodiments, the fabric has a weight of 175gsm to 225 grams per square meter (gsm). In embodiments, the weight of the fabric is 100 gsm. In embodiments, the weight of the fabric is 150 gsm. In an embodiment, the weight of the fabric is 175 gsm. In embodiments, the weight of the fabric is 200 gsm. In embodiments, the weight of the fabric is 225 gsm. In embodiments, the weight of the fabric is 300 gsm. In embodiments, the weight of the fabric is 400 gsm.
In some embodiments of the warp-stitched, heat-treated, flame retardant, thermally insulating nonwoven fabric, the nonwoven batt is at least 40 weight percent of the total weight of the fabric, and the yarns do not exceed 60 weight percent of the total weight of the fabric. In some embodiments, the nonwoven batt is about 70 to 80 weight percent of the total weight of the fabric, and the yarns used to stitch-bond the fabric are about 20 to 30 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is about 40 weight percent of the total weight of the fabric, and the yarns used to stitch-bond the fabric are about 60 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is about 50 weight percent of the total weight of the fabric, and the yarns used to stitch-bond the fabric are about 50 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is about 60 weight percent of the total weight of the fabric, and the yarns used to stitch-bond the fabric are about 40 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is about 70 weight percent of the total weight of the fabric, and the yarns used to stitch-bond the fabric are about 30 weight percent of the total weight of the fabric. In embodiments, the nonwoven batt is about 80 weight percent of the total weight of the fabric, and the yarns used to stitch-bond the fabric are about 20 weight percent of the total weight of the fabric.
In an exemplary embodiment of the stitch-bonded, heat-treated flame retardant and insulating nonwoven fabric, the fabric is a coated nonwoven fabric (not shown) wherein a coating is applied to the fabric. In an exemplary embodiment of the coated nonwoven fabric, the coating includes one or more flame retardant chemicals. In an exemplary embodiment of the coated nonwoven fabric, the coating comprises a nanoclay. In an exemplary embodiment of the coated nonwoven fabric, the coating comprises graphite. In an exemplary embodiment of the invention, the nonwoven fabric is free of coating.
In an exemplary embodiment of a stitchbonded, heat-treated flame retardant and insulating nonwoven fabric, the nonwoven batt is made of one or more of the same fibers discussed above with respect to the nonwoven fabric, and the yarns are made of a flame retardant material such as described above. In exemplary embodiments, only the nonwoven batt comprises flame retardant fibers. In exemplary embodiments, the flame retardant fibers in the nonwoven batt render the entire stitchbonded, heat-treated flame retardant and thermally insulating nonwoven fabric flame retardant.
In an exemplary embodiment, the nonwoven batt comprises inherently flame retardant viscose fibers. In an exemplary embodiment, all of the fibers in the nonwoven batt are flame retardant viscose fibers. In embodiments, the nonwoven batt comprises a blend of fibers made of different materials. In an exemplary embodiment, the yarns of the stitchbonded, heat-treated flame retardant and thermally insulating nonwoven fabric shrink when heated to a critical temperature (which depends on the particular elastic material from which the yarns are made). In an exemplary embodiment, the fibers of the nonwoven batt comprise fibers that shrink when heated to a critical temperature specific to the material of the fibers. In an exemplary embodiment, the fibers of the nonwoven batt are comprised of fibers that shrink when heated to the critical temperature of the material specific for the fibers.
In embodiments, the fibers in the nonwoven batt comprise fibers of different deniers. In embodiments, the fibers in the nonwoven batt are comprised of fibers of about the same denier.
After stitchbonding the nonwoven batt with elastic yarns, the flame retardant and insulating nonwoven fabric is subjected to a heat treatment process. The set temperature and duration of the heat treatment process causes the stitchbonded, heat-treated flame retardant and insulating nonwoven fabric to shrink (retract) relative to the nonwoven batt in both the Machine Direction (MD) and Cross Direction (CD). For example, during the heat treatment process, the flame retardant and insulating nonwoven fabric will experience a temperature of 65 ℃ to 200 ℃ for a period of 30 seconds to 120 seconds. The set temperature and duration of the heat treatment process is selected based on the material used to stitch the elastic yarns of the nonwoven batt to elastically retract or contract the yarns. The unexpected result of subjecting the stitchbonded flame retardant and insulating nonwoven fabric to heat treatment was that the entire fabric became elastic, i.e., stretchable and resilient. In other words, after heat treatment, the nonwoven batt and the yarn stitches are stretched together in both the Machine Direction (MD) and Cross Direction (CD) without twisting or separating. In addition, the heat-treated flame retardant and insulating nonwoven fabric is resilient such that after such stretching, the fabric returns substantially to its contracted state (size and shape prior to stretching). This stretching and relaxation of the warp-stitched, heat treated flame retardant and insulating nonwoven fabric can be repeated multiple times.
In an exemplary embodiment, the heat-treated flame retardant, thermally insulating nonwoven fabric comprises a nonwoven batt stitch-bonded using elastic yarns comprising elastic fibers or a combination of elastic fibers and polyester, wherein the fabric is stretchable and resilient. Referring to fig. 13, in an embodiment, the heat-treated flame retardant and insulating nonwoven fabric 102 has a Machine Direction (MD) and a Cross Direction (CD), and the fabric 102 is stretchable in both the Machine Direction (MD) and the Cross Direction (CD). In some embodiments, the heat-treated flame retardant and insulating nonwoven fabric 102 is subjected to a heat treatment process during which the elastic yarns shrink such that the fabric 102 shrinks in both the Machine Direction (MD) and Cross Direction (CD) as shown by the dashed lines in fig. 13 as compared to the fabric 102 before being subjected to the heat treatment/heat treatment process. In embodiments, the heat-treated fabric 102 shrinks Δ L in the Machine Direction (MD)1And/or Δ L2Length (initial blank (greig) before undergoing the heat treatment processe) 5% to 65% of the fabric 102), while the heat treated fabric 102 shrinks aw in the Cross Direction (CD)1And/or Δ W2Width (20% to 70% of the original greige fabric 102 before undergoing the heat treatment process).
In another embodiment, the heat-treated fabric 102 shrinks by 5% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 50% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 45% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 40% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 35% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 30% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 25% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 20% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 15% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 5% to 10% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 65% in the Machine Direction (MD). In another embodiment, the heat treated fabric 102 shrinks by 45% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 55% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 60% to 65% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 65% in the Machine Direction (MD). In another embodiment, the heat treated fabric 102 shrinks by 45% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 55% to 65% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 60% to 65% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 60% in the Machine Direction (MD). In another embodiment, the heat treated fabric 102 shrinks by 45% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 60% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 55% to 60% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 55% in the Machine Direction (MD). In another embodiment, the heat treated fabric 102 shrinks by 45% to 55% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 55% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 50% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 50% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 50% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 50% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 50% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 50% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 50% in the Machine Direction (MD). In another embodiment, the heat treated fabric 102 shrinks by 45% to 50% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 45% in the Machine Direction (MD). In another embodiment, the heat treated fabric 102 shrinks by 15% to 45% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 45% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 45% in the Machine Direction (MD). In another embodiment, the heat treated fabric 102 shrinks by 30% to 45% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 45% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 45% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 40% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 40% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 40% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 40% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 40% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 40% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 35% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 35% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 35% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 35% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 35% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 30% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 30% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 30% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 25% to 30% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 25% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 25% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 25% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 20% in the Machine Direction (MD). In another embodiment, the heat-treated fabric 102 shrinks by 15% to 20% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 10% to 15% in the Machine Direction (MD).
In another embodiment, the heat-treated fabric 102 shrinks by 20% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 60% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 55% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 50% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 45% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 40% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 35% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 30% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 20% to 25% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 30% to 70% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 70% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 70% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 45% to 70% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 70% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 55% to 70% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 60% to 70% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks 65% to 70% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 45% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 55% to 65% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 60% to 65% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 60% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 60% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 60% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 60% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 45% to 60% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 60% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 55% to 60% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 55% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 55% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 55% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 55% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 45% to 55% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 50% to 55% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 50% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 50% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 50% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 50% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 45% to 50% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 45% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 45% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 45% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 45% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 40% to 45% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 40% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 40% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 35% to 40% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 35% in the cross-direction (CD). In another embodiment, the heat-treated fabric 102 shrinks by 30% to 35% in the cross-direction (CD).
In another embodiment, the heat-treated fabric 102 shrinks by 25% to 30% in the cross-direction (CD).
In embodiments, the length L is greater than Δ L2. In embodiments, the length Δ L1Less than Δ L2. In embodiments, the length Δ L1Is equal to Δ L2. In an embodiment, the width Δ W1Greater than Δ W2. In an embodiment, the width Δ W1Less than AW2. In an embodiment, the width Δ W1Is equal to Δ W2。
In an exemplary embodiment, the warp stitched, heat treated flame retardant and insulating nonwoven fabric has a weight of about 200gsm and is comprised of about 160gsm of a nonwoven batt comprising 100% flame retardant rayon fibers and about 40gsm of a nonwoven batt comprising 100% flame retardant rayon fibersT400 elastic yarn. Embodiments of such fabrics, for example, will be subjected to a heat treatment at a temperature of 65 ℃ to 200 ℃ for a period of 30 seconds to 120 seconds. In another embodiment, the heat treatment temperature is from 70 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 75 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 80 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 85 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 90 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 100 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 105 ℃ to 200 ℃. In another embodiment, the temperature of the heat treatmentIs from 110 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 115 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 120 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 125 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 130 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 135 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 140 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 145 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 150 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 155 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 160 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 165 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 170 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 175 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is from 180 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 185 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 190 ℃ to 200 ℃. In another embodiment, the heat treatment temperature is 195 ℃ to 200 ℃.
FIG. 1 is a cross-sectional view of a foam core mattress 30 made from the above-described heat-treated fire-blocking and insulating nonwoven fabric according to an embodiment of the present invention. Referring to fig. 1, a foam core mattress 30 includes a
In a known method of manufacturing covers for foam core mattresses, a sheet of fire retardant fabric is formed into a tube (tube) or sleeve (sock) and pulled over the foam core. The open end of the tube or sleeve is then sewn so that the fabric surrounds the foam core. This method of applying the fabric to the foam core is laborious and time consuming because the friction between the fabric and the surface of the foam core causes the fabric to resist being pulled through the surface of the core. Mattress core caps according to embodiments of the present invention allow fabric to be quickly and easily applied to the foam core. An
Fig. 2 is a schematic orthogonal view of the
In an embodiment,
Fig. 3 is a schematic top view of the fabric sheet 102 before being formed to form the
The rectangular sheet 106 of fabric 102 has a
Referring to fig. 3-5, during the forming process, edge 124 is drawn to edge 126 and edges 124, 126 are sewn to one another to form a first corner seam (seam) 148; edge 130 is pulled to edge 132 and edges 130, 132 are sewn to one another to form a
Referring to fig. 1 and 4-7, in one exemplary embodiment of the invention, after forming
Fig. 4 is a schematic orthogonal view of an exemplary
Referring to fig. 4 and 5, an exemplary
Fig. 7 is a schematic bottom view of the
The foregoing discussion of fig. 1-5 relates to an exemplary embodiment of a mattress core cap 100 (which is suitable for a
As mentioned above, previously known covers for foam core mattresses that are shaped as tubes or sleeves and pull over a foam mattress core have disadvantages, including difficulties caused by the resistance of the fabric to pull through the surface of the mattress core due to friction between the fabric and the surface of the mattress core. Referring to fig. 8-10, in another embodiment of the invention described herein, a flame retardant insulating
The flame retardant insulating
Referring to fig. 11 and 12, to install the
To avoid excessive stretching of the
In some embodiments, the heat-treated flame retardant, insulating nonwoven fabric may be laminated with another fabric (which may or may not be flame retardant) to provide a flame retardant, insulating layered composite fabric suitable for making mattress core cap 100 (fig. 1-7) or other configuration of flame retardant, fire retardant barrier for mattress cores. The heat treated flame retardant, insulating nonwoven fabric may be laminated, sealed or otherwise attached to another fabric using heat treatment, sewing techniques, adhesives or other techniques now and in the future known to those of ordinary skill in the relevant art to permanently attach the fabric layers together. For example, in some embodiments, the heat-treated flame retardant insulating nonwoven fabric described above is laminated with a woven fabric that is not flame retardant and does not contain a flame retardant chemical. In some embodiments, the heat-treated flame retardant insulating nonwoven fabric is laminated with a woven fabric that is not flame retardant and does not contain a flame retardant chemical. For example, a heat-treated flame-retardant, thermally-insulated nonwoven fabric can be laminated to a ticking fabric, and the resulting flame-retardant, thermally-insulated layered composite fabric used to cover a mattress core as a ticking (see, e.g., ticking 200 in fig. 1). In some embodiments, the above-described heat-treated flame-retardant, thermally-insulating nonwoven fabric may be provided as a continuously rolled sheet to enable or facilitate lamination of the aforementioned composite fabric with another fabric.
It should be understood that the embodiments described herein are merely exemplary in nature and that many changes and modifications may be made by those skilled in the art without departing from the scope of the invention. All such variations and modifications, including those discussed above, are intended to be included within the scope of the following claims.
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