Aspects herein are related to breathable insulated garments.
With the desire to stay active year round, there is a need for insulating garments for use during physical activity in the cooler months of the year. Conventional cold-weather garments employ down and/or synthetic fibers at different weights depending on the level of insulation desired.
The technology described herein is described in detail below with reference to the attached drawing figures, wherein:
The subject matter of the present invention is described with specificity herein to meet statutory requirements. However, the description itself is not intended to limit the scope of this disclosure. Rather, the inventors have contemplated that the claimed or disclosed subject matter might also be embodied in other ways, to include different steps or combinations of steps similar to the ones described in this document, in conjunction with other present or future technologies. Moreover, although the terms “step” and/or “block” might be used herein to connote different elements of methods employed, the terms should not be interpreted as implying any particular order among or between various steps herein disclosed unless and except when the order of individual steps is explicitly stated.
At a high level, aspects herein relate to methods of constructing insulated garments and garments resulting therefrom. Traditionally, down has been the preferred insulation material due to its light weight and effective thermal insulation properties. However, care of down filled garments may be difficult and may need specialized laundering because of its tendency to clump up. Another potential disadvantage of down is that although its insulation properties are maintained when dry, if the down within the garment becomes wet for one reason or another, its insulation properties may become compromised and decrease significantly. Additionally, use of down often requires stitching panels of material together to form horizontally oriented chambers and blowing the down into the horizontally oriented chambers with specialized machinery, which can be a messy process.
Further, the cost of down may be high, depending on the quality of down. That is why alternatives to down such as cotton and polyfill fibers have been used. However, even though cotton and polyfill fibers may maintain their insulation properties better than down when wet, like down, cotton and polyfill fibers may also depend upon horizontally oriented chambers for an even distribution throughout the garment, and like down, may also have a tendency to clump up when wet or laundered. That is why most traditional insulated garments are formed from weatherproof materials to protect the wearer and the insulation materials from environmental elements such as, for example, rain and snow. However, traditional insulated garments formed from weatherproof materials may trap moisture vapor produced by the wearer, which may result in wearer discomfort.
One solution to the clumping of traditional thermally insulating materials when wet or after laundering has been to use non-woven polymer sheets instead of materials such as down or loose poly-fill fibers, for example. As used throughout this disclosure, terms such as “non-woven polymer sheet,” “poly-fill sheet,” “thermally insulating sheet material,” and “thermally insulating fill sheet” may be used interchangeably herein. Further, as used throughout this disclosure, terms such as “sections of non-woven polymer material,” “sections of poly-fill material,” “sections of thermally insulating sheet material,” and “sections of thermally insulating fill material” may be used interchangeably herein. These non-woven polymer sheets are easier to work with due to their cohesive structure. Further the use of non-woven polymer sheets or sections of non-woven polymer material imparts warmth to the finished garment, which may not be compromised when wet. Moreover, in some examples, the non-woven polymer materials described herein may be generally hypoallergenic, may not need special laundering, may have short dry times, and may still provide warmth even when wet. In some examples, they also may not need specialized handling or machinery when forming the garment which may potentially reduce manufacturing steps and/or costs. However, these sheets, depending on the amount of insulation desired, may become heavier than materials such as down. Therefore, the methods of constructing the insulated garments in accordance with the technology described herein, may utilize non-woven polymer sheets or sections of non-woven polymer material comprising one or more voided portions in order to make the resulting garments lightweight but still insulating.
Additional advantages may be obtained by using non-woven polymer sheets and/or sections of non-woven polymer material having voided portions. Because of their non-woven structure formed, for example, by entangling synthetic microfibers (i.e., fibers of one denier or less), synthetic fibers or filaments, a combination of synthetic and natural fibers or filaments, they are able to maintain a cohesive unitary structure as opposed to, for instance, loose poly-fill fibers and/or down. As such, they allow for the creation of voided portions in the non-woven polymer sheets, wherein the voided portions can take on any desired shape and size. Further, depending on the material used to form the garment layers, if the garment layers are formed from sheer, translucent, or in other words “see through” pliable materials, the presently described technology may become visible through the garment layers, thereby adding a visual appeal dimension to the final constructed garment.
Furthermore, the use of non-woven polymer sheets comprising one or more voided portions allows for the provision of varied levels of insulation within the same garment. For example, the level of insulation may be varied by changing the thickness of the thermally insulating sheet material at different locations, and/or the thermal insulation may be localized by providing insulated sections only at particular areas of the garment aligning with temperature sensitive areas in a wearer's body to provide insulation only where needed, thereby reducing garment bulkiness. In a different example, the level of insulation and/or the overall weight of the garment may be varied by adjusting the amount (e.g., volume, weight percent, and the like) of voided portions in the thermal insulation material. For example, increasing the amount (e.g., volume, weight percent, and the like) of voided portions in a thermally insulating sheet material may lead to a lighter overall weight of the garment as well as a decreased amount of thermal insulation provided by the thermally insulating sheet material. Further, in some examples, a first portion of a thermally insulating sheet material may have a first amount of voided portions and a second portion of the thermally insulating sheet material may have a second amount of voided portions where the first amount of voided portions is less than the second amount of voided portions thereby leading to an amount of thermal insulation of the first portion of the thermally insulating sheet material being greater than an amount of thermal insulation of the second portion of the thermally insulating sheet material.
In another exemplary aspect, garments constructed in accordance with aspects herein may be provided with one or more vent openings for allowing exchange of air, gas, heat, moisture, and the like, between an interior of the garment and an external environment of the garment. For example, garments constructed in accordance with aspects herein may be provided with one or more vent openings for allowing heat and moisture from perspiration to escape into an external environment thereby allowing an environment internal to the garment to stay regulated preventing discomfort from overheating. As another example, vent openings in a garment may contribute to an increased evaporation rate of sweat formed by a wearer of the garment thereby providing increased cooling to the wearer during certain conditions. In particular, providing the one or more vent openings may be advantageous when using water resistant or water repellant materials to form the garment layers because these materials may otherwise cause the heat and moisture from perspiration to become trapped within the garment, thereby making a wearer increasingly uncomfortable. The one or more vent openings in accordance with aspects herein may be provided evenly throughout the garment, or they may be provided at strategic areas of the garment to allow venting where needed most (i.e. areas aligning with areas of the body of a wearer that have higher heat and moisture release such as, armpits, lower back, upper back, and the like). Furthermore, the number, density, and/or size of the vent openings may be varied at different areas of the garment to provide different amounts of ventilation at different areas of the garment.
As described herein, use of a thermally insulating sheet material that comprises one or more voided portions also allows for the creation of a lightweight insulating garment. For example, the amount of thermal insulation material removed compared to its non-voided counterpart, may be measured as a weight percent. For example, when a piece of thermally insulating sheet material has a weight of 100 g/cm2 and 10% by weight is removed from it to form one or more voided portions in the thermally insulating sheet material, 10 g/cm2 are removed from the thermally insulating sheet material so that the thermally insulating sheet material having the one or more voided portions ends up weighing 90 g/cm2, which may be the same weight or lighter than its down counterpart (down counterpart refers to, for example, a garment providing the same thermal insulation levels as a garment constructed with the thermally insulating sheet material having the one or more voided portions).
In accordance with aspects herein, the thermally insulating sheet material may have 5% by weight, 10% by weight, 20% by weight, 30% by weight, 40% by weight, 50% by weight, or between 5% and 60% by weight, between 15% and 50% by weight, between 25% and 45% by weight, between 20% and 35% by weight, between 10% and 25% by weight, and the like removed to form the one or more voided portions. The size and/or shape of the voided portions may be varied within a panel of thermally insulating sheet material, or the voided portions may be chosen to be of a uniform shape and/or size within the garment panel. Additionally, in some examples, different areas of the thermally insulating sheet material may have different weight percents removed to form different amounts of voided portions in the different areas of the thermally insulating sheet material.
Continuing, depending on the ability of a particular thermally insulating sheet material to hold its shape after multiple laundering cycles, the percent by weight removed from the thermally insulating sheet material to form the one or more voided portions may vary. For example, a thicker or denser (more tightly packed) thermally insulating sheet material may be more sturdy and withstand deformation better than a lighter weight or thinner thermally insulating sheet material. Another aspect that may play a role on the sturdiness of the thermally insulating sheet material may be, for example, the length of individual fibers used in the formation of the thermally insulating sheet material. In other words, the greater the length of individual fibers in the thermally insulating sheet material, the sturdier the thermally insulating sheet material may be. Therefore, it may be possible to form larger sized voided portions in the thicker and/or denser thermally insulating sheet material than in the lighter weight and/or thinner thermally insulating sheet material, or in the thermally insulating sheet material having individual fibers that are longer in length rather than the thermally insulating sheet material having individual fibers that are shorter in length.
In exemplary aspects, the thermally insulating sheet material may be reinforced so that it is better able to withstand repetitive wear, laundering, and the like. One way of reinforcing the thermally insulating sheet material may be by providing a scrim layer on one or both surfaces of the thermally insulating sheet material. The scrim layer may be adhesively bonded, heat bonded/fused, or both, to the thermally insulating sheet material. The thermally insulating sheet material may also be reinforced by heat treating one or both surfaces of the thermally insulating sheet material to form a skin layer on the heat treated surface(s). The skin layer may be formed by partially or fully fusing together the surface fibers forming the thermally insulating sheet material.
Alternatively or in addition to one or more of the reinforcing methods described above, the thermally insulating sheet material in accordance with aspects herein, may be stabilized within a garment construction through the provision of one or more non-garment/article forming seams securing the thermally insulating sheet material to one or both garment layers (one garment layer on either surface of the thermally insulating sheet material), at portions of the thermally insulating sheet material that correspond to non-voided portions in the thermally insulating sheet material. In one aspect, the greater the number of non-garment/article forming seams used to secure the thermally insulating sheet material to one or both garment layers, the greater its stability and the better it is able to maintain its structural integrity when subjected to, for example, laundering and repeated use, thereby being less subjective to deformation and/or warping. However, the number of non-garment/article forming seams that may be needed to stabilize the thermally insulating sheet material within garment layers may be decreased when the voided thermally insulating sheet material comprises a high enough density and/or is reinforced. For instance, when the voided thermally insulating sheet material is considered to be structurally sound, a fewer number of tack points may be needed to hold the voided thermally insulating sheet material in place with respect to the garment layers in the finalized garment. Additionally, the higher density thermally insulating sheet material and/or the reinforced thermally insulating sheet material may be able to accommodate larger voided portions than the lighter density thermally insulating sheet material and/or non-reinforced thermally insulating sheet material.
In accordance with the technology described herein, in a method of construction that utilizes non-woven polymer sheets or thermally insulating sheet materials, one or more selected portions of the thermally insulating sheet materials may be removed to create one or more openings or voided portions in the thermally insulating sheet material prior to or after shaping the thermally insulating sheet material according to specifications for at least one garment panel. The one or more openings or voided portions may be created by, for example, manual cutting, die cutting, laser cutting, ultrasonic cutting, and the like. An advantage of using laser or ultrasonic cutting may be that internal perimeter edges of each of the one or more voided portions may become sealed by the formation of, at least in part, a skin layer resulting from the fusion of at least a portion of surface fibers in the internal perimeter edges of the one or more voided portions. The skin layer may contribute to the structural integrity of each opening or voided portion in the thermally insulating sheet material. Alternatively, the one or more openings or voided portions may be integrally formed when manufacturing the thermally insulating sheet material. Further, at least two garment forming layers of pliable material may be provided, also according to the specifications for the at least one garment panel. The voided thermally insulating sheet material may be interposed between the two layers of pliable material forming a “sandwich” configuration for the at least one garment panel, resulting in the voided thermally insulating sheet material as a second layer of thermally insulating sheet material “sandwiched” between a first layer of pliable material and a third layer of pliable material.
In accordance with aspects herein, the second layer of thermally insulating sheet material may be first aligned with and secured to one of the first layer of pliable material or the third layer of pliable material at one or more portions corresponding to non-voided portions of the second thermally insulating sheet material through one or more non-garment/article forming seams or tack points. The other of the first layer of pliable material or the third layer of pliable material that is not secured, may be positioned adjacent the second layer of thermally insulating sheet material, such that the second layer of thermally insulating sheet material is positioned between the first layer of pliable material and the third layer of pliable material. Alternatively, the first layer of pliable material, the second layer of thermally insulating material and the third layer of pliable material may be secured to each other at one or more portions corresponding to non-voided portions of the second thermally insulating sheet material through one or more non-garment/article forming seams or tack points to form the at least one garment panel. The at least one garment panel may be used at least in part to form the garment.
In a First Realization in Accordance with Aspects Herein:
Garments that are produced according the method described above may be light weight, low maintenance, versatile and may have thermal insulation properties that perform similar to or better than their down counterparts, for example. The garments may have a first layer and a third layer of pliable material with a second layer of thermally insulating sheet material interposed between the first layer and the third layer of pliable material, where the second layer of thermally insulating sheet material comprises one or more voided portions. The second layer of thermally insulating sheet material may be secured to one of the first layer of pliable material or the third layer of pliable material, or may be secured to both the first layer of pliable material and the third layer of pliable material through one or more non-garment/article forming seams formed at one or more portions corresponding to non-voided areas in the second layer of thermally insulating sheet material.
In a Second Realization in Accordance with Aspects Herein:
Further, the garments described herein may be configured to allow moisture and/or heat to escape from the garment through one or more vent openings. The one or more vent openings may be formed on an affixed portion of the first layer of pliable material and the third layer of pliable material, the one or more vent openings extending through the first and third layers of pliable material at the affixed portion. The affixed portion may be formed by affixing a first portion of an interior surface of the first layer of pliable material and a corresponding second portion of an interior surface of the third layer of pliable material that are in alignment with at least one voided portion in the one or more voided portions of the second layer of thermally insulating sheet material. The affixing step may be performed by adhering the interior surfaces of the first layer and the third layer of pliable material. Alternatively, the one or more affixed portions may be formed by stitching the first and the third layers of pliable materials together forming boundaries for each affixed portion. And in yet another aspect, the one or more affixed portions may be formed by both adhering the interior surfaces of the first and third layers of pliable material and by adding stitching to boundaries of the affixed portions, thereby reinforcing each affixed portion in the one or more affixed portions.
In a Third Realization in Accordance with Aspects Herein:
The technology described herein is further directed to insulated garments having zonal insulation, or in other words, garments that comprise insulation sections that are located at specific locations on the garment. The individual insulation sections may be constructed as described in the method of construction above, but in place of a whole garment panel, each individual insulation section may have a size that is smaller than the garment panel onto which it will be installed. Furthermore, each insulation section may have a specific shape suitable for adequate coverage and protection to a specific body part of a wearer. The insulation sections according to aspects herein may be installed on an outer surface of a garment layer by for example, stitching or otherwise bonding a perimeter of each insulation section to the outer surface of the garment at specified locations, thereby adding an additional visual appeal to the garment. A particular garment may comprise one or more insulation sections installed on to it. When multiple insulation sections are installed on one garment, each insulations section may be adequately sized and shaped according to particular specifications for the garment and its particular location on the garment. For example, a chest insulation section may be configured to be larger than a shoulder insulation section, or a collar insulation section.
As such it is envisioned that garments comprising the thermal insulation sections in accordance with aspects herein, are geared to provide localized thermal insulation to only certain areas of a wearer's body that may be more sensitive to temperature changes, without having to wear a fully insulated garment in the form of a jacket/coat. Exemplary garments that may include the insulation sections in accordance with the aspects described herein include: biking gear, running gear, and the like, that is meant to be conforming to a wearer's body. Specific examples will be discussed below with reference to the figures.
The insulation section, like the garment panels constructed in accordance with aspects herein, may further comprise one or more vent openings to form vented-insulation sections. When vented, the insulation sections may allow moisture and/or heat to escape from the garment through one or more vent openings formed through the insulation sections. Each insulation section may comprise, for example, a first layer and a third layer of pliable material with a second layer of thermally insulating sheet material having one or more voided portions interposed between the first layer and the third layer of pliable material. The vent openings, if provided, may be formed in affixed portions by bonding a first portion of an interior face of the first layer of pliable material and a corresponding second portion of an interior face of the third layer of pliable material that are in alignment with at least one voided portion in the one or more voided portions of the second layer of thermally insulating sheet material to form at least one affixed portion. Then, one or more vent openings may be formed at the affixed portion that extend through all layers of the affixed portion.
In a Fourth Realization in Accordance with Aspects Herein:
The garments in accordance with aspects herein may comprise integrally woven garment panels, each garment panel having, for example, a first woven layer of pliable material with a first inner surface and a first outer surface, a second woven layer of pliable material comprising a second inner surface and a second outer surface, and a woven layer of thermal insulation integrally woven with and interposed between the first woven layer and the second woven layer of pliable material, wherein the woven layer of thermal insulation comprises, for example, a plurality of float yarns.
Further, the integrally woven layers of the garment panel may comprise one or more integrally woven affixed portions at one or more portions not comprising the float yarns. In other words, the first layer of pliable material and the second layer of pliable material are integrally woven together to form a single layer of pliable material at the affixed portion. Optionally, one or more openings may be formed through one or more of the affixed portions to form one or more vent openings. The vent opening may be, for example, integrally formed in the weaving process, it may be laser cut post weaving, or it may be die cut post weaving. It is envisioned that many other methods of forming the vent openings are available, and they are all considered to be within the scope according to aspects described herein.
In a Fifth Realization in Accordance with Aspects Herein:
The garments in accordance with aspects herein may comprise integrally knit garment panels, each garment panel having, for example, a first knit layer of pliable material with a first inner surface and a first outer surface, a second knit layer of pliable material comprising a second inner surface and a second outer surface, and a knit layer of thermal insulation integrally formed from and interposed between the first knit layer and the second knit layer of pliable material, wherein the knit layer of thermal insulation comprises, for example, tie yarns, loops (i.e. like in a terry fabric), and the like.
Further, the integrally knit layers of the garment panel may comprise one or more integrally knit affixed portions at one or more portions not comprising the tie yarns and/or the yarn loops. In other words, the first layer of pliable material and the second layer of pliable material are integrally knit together to form a single layer of pliable material at the affixed portion. Optionally, one or more openings may be formed through one or more of the affixed portions to form one or more vent openings. The vent opening may be, for example, integrally formed in the knitting process, it may be laser cut post knitting, or it may be die cut post knitting. Like in the woven example above, it is envisioned that many other methods for forming the vent openings are available, and they are all considered to be within the scope according to aspects described herein.
Materials of Construction
The garments in accordance with the technology described herein may be constructed using natural woven or knit fabrics (e.g., cotton, silk, hemp, etc.) synthetic woven or knit fabrics (e.g., polyester, rayon, etc.), non-woven materials (e.g., leather, faux leather, pliable plastics, rubbers, thermoplastics, polymer materials, and the like) and/or combinations thereof. The woven or knit fabrics may be optionally treated with down/fill-proofing chemical treatments, and/or water repellants that may also act as down/fill-proofing treatments, such chemical treatments referred to as DWR (durable water repellant). Although DWR is a waterproofing chemical treatment, in addition to waterproofing the fabric, it is also very useful for down/fill-proofing fabrics, especially light and ultra-light weight fabrics. For example, fabrics that may particularly benefit from DWR treatment are light fabrics (89 g/m2 to 30 g/m2) and ultra-light fabrics (29 g/m2 or lighter). Heavier fabrics, such as fabrics with weights in the range of 90 g/m2 to 149 g/m2 or even 150 g/m2 to 250 g/m2 or higher, may be inherently more resistant to fill/down and may or may not need a chemical treatment depending on the specific type of fabric/textile and therefore, may not need to be treated with a down/fill proofing chemical treatment.
Both heavy and light-weight fabrics may be used in garments in accordance with the technology described herein. Lighter weight fabrics may be more desirable in the manufacture of athletic and/or insulating garments used during high aerobic activity, in order to minimize the garments' weight.
Form Factor
The insulated garment described herein can take several forms. In one example of the garment in accordance with the technology described herein, the garment may be a standalone garment. The garment may be in the form of a vest covering a person's body core area, a jacket or coat with sleeves, pants, a total body suit, ski pants, a fleece, a clothing liner, and the like.
Alternatively, the garment in accordance with the technology described herein may be used as a removable interior-insulating panel having an exterior shell which may or may not be weather proof. This interior-insulating panel may also be worn as a standalone garment when detached from the exterior shell Like in the previous example, the removable interior-insulating panel may be presented as a vest, a jacket, a body suit, and the like, depending on the type of garment and protection desired. For example, if the exterior shell is a long sleeved jacket, the interior-insulating panel may be presented as a vest, a jacket, or a jacket with removable sleeves to convert into a vest, depending on the amount of insulation desired. The interior-insulating panel may be fastened to the exterior shell by a zipper mechanism, buttons, hook-and-loop fasteners, or other suitable fastening mechanism or combination of fastening mechanisms.
The garments in accordance with aspects herein may be worn over or engineered into a base layer, such as in the case of a vest. In other words, instead of being removable, an exterior insulating panel in accordance with the technology described herein may be permanently attached to the base layer by using, for example, stitching, bonding, welding, and the like or by integrally forming the garment layer by, for example, knitting or weaving. Moreover, the garments may be engineered into an exterior shell. In other words, instead of being removable, an interior insulating panel in accordance with the technology described herein may be permanently attached to the exterior shell. This may be achieved by permanently affixing the exterior shell to the interior insulating panel at one or more areas using, for instance, stitching, bonding, welding, adhesives, and the like. Alternatively, an interior insulating panel may be integrated into an exterior shell panel by, for instance, integrally forming the interior insulating panel with the exterior shell using an engineered knitting and/or weaving process. Further, the breathability of the garment panels described above, may be increased by providing one or more vent locations at predetermined areas of the garment panel. Any and all aspects, and any variation thereof, are contemplated as being within the scope herein.
Definitions
As used throughout this disclosure, positional terms used when describing, for instance, a garment, such as “anterior,” “posterior,” “inferior,” “superior,” “lateral,” “medial,” and the like are to be given their common meaning with respect to the garment being worn by a hypothetical wearer standing in anatomical position.
Unless indicated otherwise, terms such as “affixed,” “coupled,” “secured,” and the like may mean releasably affixing two or more elements together using for instance, structural differences between elements, releasable adhesives, snaps, buttons, hook-and-loop fasteners, and the like. These terms may also mean permanently affixing two or more elements together using, for example, stitching, bonding, adhesives, welding, and the like.
Unless indicated otherwise, terms such as “proximate” or “adjacent” may mean within 0 cm to 5.0 cm of a designated reference point.
Exterior panel: As used herein the phrase “exterior panel” describes a panel on the exterior of the garment. The exterior panel may be exposed to the external environment, or may not be exposed to the environment, for example, if the garment is worn under another garment or layer.
Affixed portion: a portion of an interior surface of a first layer of pliable material affixed by stitching, bonding, welding, and the like, to an interior surface of a second layer of pliable material, at a location on the first and second layers of pliable material aligning with a voided portion in a layer of thermally insulating sheet material interposed between the first and the second layers of pliable material. The first layer of pliable material, the layer of thermally insulating sheet material, and the second layer of pliable material are in alignment when they are layered, for example, on top of each other in the z-direction, and are extending along an x,y-plane. In other words, the alignment of the interior surface of the first layer of pliable material and the interior surface of the second layer of pliable material with a voided portion in the thermally insulating sheet material occurs, for example, in the z-direction, where the interior surfaces of the first and second layers of pliable material are able to be affixed to each other to form the affixed portion without any interference from the thermally insulating sheet material. The affixed portions are configured to help anchor the thermally insulating material to prevent shifting of the thermally insulating material, and to maintain the structural integrity of the thermally insulating material, due to repeated use and especially during laundering cycles.
Vent opening: As used herein the phrase describes an opening that is formed on an affixed portion or a seam, and extends through the first layer of pliable material and the second layer of pliable material at the affixed portion or seam, thereby directly or indirectly connecting an interior environment internal to the garment (near a wearer's body when the garment is worn), to an exterior environment external to the garment (exposed to environmental elements). The vent opening may be formed at a central area or central portion of the affixed portion. The central area is one that is, for example, located equidistant from respective vertices of the affixed portion when the affixed portion comprises a shape having linear sides, or is located at the center of the affixed portion when the affixed portion comprises, for instance, a circular shape.
Interior panel: As used herein the phrase “interior panel” describes a panel inside of or interior to the exterior panel. A garment may have multiple interior panels.
Voided portion/area: As used herein the phrases “voided portion,” and/or “voided area” describe an opening, a hole, or an empty space (only air is present). The voided portions in the thermally insulating sheet material in accordance with aspects herein, may be formed by, for example, manual cutting, die cutting, laser cutting, ultrasonic cutting, and the like. An advantage of using laser or ultrasonic cutting may be that internal perimeter edges of each of the one or more voided portions may become sealed by the formation of, at least in part, a skin layer resulting from the fusion of at least a portion of surface fibers in the internal perimeter edges of the one or more voided portions. The skin layer may contribute to the structural integrity of each opening or voided portion in the thermally insulating sheet material. Alternatively, the voided portions of the thermally insulating sheet material in accordance with aspects herein, may be formed during the manufacturing of the thermally insulating sheet material to create a thermally insulating sheet material having one or more voided portions.
Non-voided portion/area: As used herein the phrase “non-voided portion,” and/or “non-voided area” describe the tangible portion or area surrounding an opening, a hole, or an empty space (only air is present). The non-voided portions/areas in the thermally insulating sheet material in accordance with aspects herein, are the tangible portions or areas in the thermally insulating sheet material that surround the voided portions in the thermally insulating sheet material. In other words, the non-voided portions/areas, comprise the tangible sections of the material that provide structural integrity to the material.
Water-Resistant Fabric: As used herein “water-resistant fabric” is a fabric that is substantially impervious to water. In some exemplary aspects, the term “water-resistant fabric” may be defined as a fabric that has greater than 1,000 mm of water resistance, which is the amount of water, in mm, which can be suspended above the fabric before water seeps through. However, values above and below this threshold are contemplated as being within the scope herein.
Non-breathable Fabric: As used herein “non-breathable fabric” is fabric that exhibits a low rate of moisture vapor transmission. In some exemplary aspects, a fabric may be defined as being non-breathable when it has a moisture vapor transmission rate less than 1000 (g/m2/d), which is the rate at which water vapor passes through the fabric, in grams of water vapor per square meter of fabric per 24-hour period (g/m2/d). However, values above and below this threshold are contemplated as being within the scope herein.
Weather-Resistant Fabric: As used herein “Weather-Resistant Fabric” is a fabric that is generally resistant to water and/or wind. In some instances, a weather-resistant fabric may comprise a fabric that is substantially impervious to water and exhibits a low rate of moisture vapor transmission.
Passage: As used herein the term “passage” is a space between garment layers where the garment layers are not directly connected. The passage is configured to and allows for the passage of moisture or moisture vapor and/or air.
Insulation section: As used herein refers to a pod-type construction wherein a first/interior layer of pliable material and/or a second/exterior layer of pliable material are affixed to a voided thermally insulating sheet material disposed between them. The pod type construction is configured to cover only a portion of an exterior surface of a garment, for example, less than 70% of an exterior surface of the garment, between 20% and 50% of an exterior surface of the garment, between 30% and 60% of an exterior surface of the garment, and the like.
First/interior layer/panel: As used herein refers to a layer of pliable material comprising a first/exterior surface and an opposite second/interior surface where the first/exterior surface is configured to face toward a body surface of a wearer when the garment is worn, and where the second/interior surface is configured to face toward a thermally insulating material contained within a chamber.
Second/exterior layer/panel: As used herein refers to a layer of pliable material comprising a first/exterior surface and an opposite second/interior surface where the first/exterior surface is configured to face toward an external environment, away from the body surface of a wearer when the garment is worn, and where the second/interior surface is configured to face toward a thermally insulating material contained within a chamber.
Seam: As used herein refers to a tack or stitched point; a stitched line; a quilting stitch; adhered/fused/bonded point/area/portion/section; and/or adhered/fused/bonded line, to join or secure two or more layers of material together, or two or more garment/article panels.
Garment/article forming seam: As used herein, a garment/article forming seam is a seam that is configured to join two or more garment/article panels together to form a garment/article. More specifically, garment/article forming seams, as used herein, are configured to join two or more garment/article panels at their respective edges to form the garment/article. Examples of garment/article forming seams may comprise seams that join sleeve panels to body panels of an upper body garment, seams that join front and back panels of an upper or lower body garment, and the like.
Non-garment/article forming seam: As used herein, a non-garment/article forming seam is a seam that does not join two or more garment/article panel edges together but rather, secures two or more layers (e.g., inner, outer, and/or middle layers) of a single garment/article panel to each other. Non-garment/article forming seams help to improve the structural stability of the garment/article panel and may be present alone or in combination with one or more affixed portions, as described above. The non-garment/article forming seams may be formed by, for example, stitching the different layers of the garment/article panel to each other and/or by using an adhesive or bonding material to adhere the layers together. Non-garment/article forming seams may further add visual interest to the garment panel when in the form of, for example, embroidery.
Baffle: As used throughout this disclosure, the term “baffle” may be defined as a chamber formed by, for example, the first layer of pliable material and the second layer of pliable material where the chamber encloses one or more voided portions of a layer of thermally insulating sheet material that is placed between first layer of pliable material and the second layer of pliable material, where the chamber is delineated by the one or more seams.
Non-woven: As used throughout this disclosure, the term “non-woven” may be defined as a mat or sheet-like structure formed by entangling microfibers, fibers, or filaments of a material, or depositing filaments of a material into a mold to form a cohesive sheet-like structure. The polymer sheet may comprise a single layer or multiple layers.
As briefly described above, aspects herein contemplate a method of forming an insulated vented garment using non-woven polymer sheets such as a thermally insulating poly-fill sheet. Aspects herein further contemplate an insulated vented garment formed using non-woven polymer sheets. In exemplary aspects, the polymer material may comprise a single layer or multiple layers. Further, in exemplary aspects, the polymer material may comprise polyester microfibers, fibers, or filaments. The non-woven polymer sheet is made to be lighter than a conventional non-woven polymer sheet through the formation of one or more voided portions in the non-woven polymer sheet. As such, aspects of the present technology allow for the provision of good insulation properties due to heated air in between garment layers (heated by a wearer's intrinsic body heat) being trapped and able to circulate in the one or more voided portions and in between the entangled fibers forming the non-woven polymer sheet.
The voided thermally insulating sheet material in accordance with aspects herein is highly versatile, light weight, and durable, without sacrificing its thermally insulative properties. In fact, depending on the weight (thickness) of the thermally insulating sheet material, its insulative properties may be comparable or better than down, while remaining lightweight. Furthermore, the voided thermally insulating sheet material allows for a more versatile garment construction not restricted to horizontally extending baffles, as is the case with down or loose synthetic fibers. Moreover, the voided thermally insulating sheet material in accordance with aspects herein reduces the bulkiness of garments without sacrificing insulation, thereby allowing for garment constructions that are less restrictive, breathable, hypoallergenic (no animal products such as down), and visually appealing. The air present in the voided portions may also allow for a more even heat convection and distribution throughout the garment. Additionally, the technology in accordance with aspects herein allows for the provision of different levels of insulation within a single garment panel by, for example, varying the thickness of the thermally insulating sheet material at different regions of the garment and/or varying the size and/or frequency of the voided portions in the thermally insulating sheet material within the same garment panel.
In exemplary aspects, the insulating garment may be manufactured from a light-weight fabric. In some examples, the light-weight fabric may be a translucent (see through) light weight fabric, which allows the viewing of the materials positioned underneath the translucent light-weight fabric or textile, thereby, also adding a visual dimension to the garments. Seams separating chambers or pockets may be located at various areas of the garment, spaced at varying intervals, and may have any orientation and/or shape. In another aspect, one or more portions of the insulating zones and/or the vented garment may be constructed using a weaving or knitting process (e.g., a weaving or knitting machine may be programmed to form various structures or constructions described herein). For example, such weaving or knitting processes may be used to form a seamless or nearly seamless garment or portions thereof.
Turning now to
According to the present example, the voided portions 120 in the second layer of thermally insulating sheet material 121 are evenly spaced and comprise a uniform size and shape throughout. However, it is contemplated that the second layer of thermally insulating sheet material 121 may be manufactured with one or more voided portions of any desired shape and size, suitable for the particular garment construction at hand. Alternatively, or in addition to, the one or more voided portions 120 may be formed on the second layer of thermally insulating sheet material 121 by, for example, manual cutting, die cutting, laser cutting, ultrasonic cutting, and the like. An advantage of using laser or ultrasonic cutting may be that internal perimeter edges of each of the one or more voided portions 120 may become sealed by the formation of, at least in part, a skin layer resulting from the fusion of at least a portion of surface fibers in the internal perimeter edges of the one or more voided portions 120. The skin layer may contribute to the structural integrity of each opening or voided portion 120 in the thermally insulating sheet material 121. The one or more voided portions 120 may be formed to have a desired shape and size suitable for use in accordance with aspects herein.
The one or more voided portions 120 may, for example, have a uniform shape and size throughout the second layer of thermally insulating sheet material 121 (as shown in
The second layer of thermally insulating sheet material 121 may be tacked to one of the first layer of pliable material 111 or the third layer of pliable material 131, or both the first layer of pliable material 111 and the third layer of pliable material 131 at one or more discrete tack points in place of, or in addition to, the continuous seams 130, shown with respect to
In an additional or alternative aspect, the one or more tack points may be formed at portions on the first and/or third layers of pliable material 111 and 131 corresponding to one or more voided portions 120 of the second layer of thermally insulating sheet material 121. This is accomplished by adhesively or otherwise, bonding the second/internal surfaces 141 and 151, respectively, at the one or more voided portions to form one or more affixed portions. Similar to the tack stitching, the locations of the affixed portions may be strategically chosen to form a desired pattern. In accordance with aspects herein, the affixed portions may provide a further advantage in that they may serve as locations for one or more vent openings that will be described in further detail below.
The one or more voided portions 120 in accordance with aspects herein, may range in size between for example, 0.1 cm-100 cm, 0.5 cm-50 cm, 1 cm-25 cm, 2 cm-10 cm, 0.1 cm-10 cm, 0.5 cm-5 cm, and the like, measured on the tallest or widest side of the voided portion 120 from a starting point on one side of the voided portion 120 to an ending point on the other side of the voided portion 120. As described above, the voided portions 120 may be formed to have a size gradient. For example, the voided portions 120 may be round voids having a diameter ranging from 0.1 cm-3 cm, with the biggest voided portion 120 having the biggest diameter being present in a first area of the garment and the smallest voided portion 120 having the smallest diameter being present at a second area of the garment, with intermediately sized voided portions 120 located between the biggest and the smallest voided portions 120.
Having voided portions of different sizes at different locations on the garment can be used to add a visual effect when the technology is made to be visible and/or to vary the level of insulation at the different locations (even when the technology is not made to be visible). This is because the level of insulation can be adjusted by the removal of thermally insulating material from the second layer of thermally insulating sheet material 121, after a threshold value is reached. For example, the insulation provided by a layer of thermally insulating material may not be particularly different between a non-voided state and a 10% by weight voided state. However, the level of insulation provided by the layer of thermally insulating material may slightly decrease starting at a 15% by weight voided state. It can be appreciated that the threshold value will be different for different types of thermally insulating sheet materials depending on the composition and or weight/thickness of the thermally insulating sheet material used. Another advantage of the garment construction in accordance with aspects herein is that the air present in the voided portions 120 of the second layer of thermally insulating sheet material 121 may aid in heat distribution and retention of heat by allowing the air located around the second layer of thermally insulating sheet material 121 and in between the first layer of pliable material 111 and the third layer of pliable material 131, to be warmed by the wearer's body heat and to be evenly distributed throughout the garment.
The one or more voided portions 120, along with having the functionality of providing varied levels of insulation (after the threshold value is reached), may also provide a visual effect for the garment. In particular, the visual effect may be achieved when using pliable materials that are translucent, see through, or almost see through, as the garment layers. For example, the first layer of pliable material 111 may be used as an exterior translucent garment layer, which would allow the voided portions 120 in the second layer of thermally insulating sheet material 121 to be viewed through the first layer of pliable material 111. In other aspects, both the first and the third layers of pliable material 111 and 131 may be made of translucent material. The translucent pliable materials may comprise, for example, ultra-thin/knit woven textiles such as nylon, thermoplastic materials, clear plastic-type materials, and the like.
As described above, in some cases textiles that are ultra-thin may need to be chemically treated to make them resistant to the fill material penetrating the textile, either partially or entirely. An exemplary treatment may include, for example, a durable water repellant (DWR). Additionally, in accordance with aspects herein, the textiles in accordance with the present disclosure may be formed, for example, by weaving or knitting a textile of sufficient weight to retain the fill material. As such both of the first layer of pliable material 111 and the third layer of pliable material 131 may comprise an ultra-thin textile material treated with DWR. Alternatively, when the first layer of pliable material 111 is an exterior layer, it may comprise the translucent textile/fabric layer, while the third layer of pliable material 131 (since it is an interior layer) may comprise a moisture regulation knit or woven synthetic textile/fabric, a mesh type fabric, a soft natural textile/fabric (cotton, hemp), and the like. It is contemplated that these are merely exemplary configurations and that there are many other configurations possible, which would still be within aspects herein.
Moving on to
In
Turning now to
Turning now to
In accordance with aspects herein, the second layer of thermally insulating sheet material 321 may be secured to only the first layer of pliable material 311 (shown) or only to the third layer of pliable material 331, through one or more seams 330, for example, formed by stitching, tacking, adhesives, welding, or any other suitable method. Or the second layer of thermally insulating sheet material 321 may be secured to both the first layer of pliable material 311 and the third layer of pliable material 331 (as shown in
With respect to
As further observed, the second layer of thermally insulating sheet material 321 is interposed or positioned between the first layer of pliable material 311 and the third layer of pliable material 331. As seen in this example, each baffle 310 is delimited by one or more seams 330 formed on non-voided portions 360 of the second layer of thermally insulating sheet material 321, where each of the one or more seams 330 secures the first layer of pliable material 311 to the second layer of thermally insulating sheet material 321 and to the third layer of pliable material 331. In this particular example, the seams 330 will be visible on external surfaces 340 and 350 of the first layer of pliable material 311 and the third layer of pliable material 331 respectively. Each interior surface 341 and 351 of the first layer of pliable material 311 and the third layer of pliable material 331 respectively, are in contact with one of the surfaces of the second layer of thermally insulating sheet material 321.
It is within an aspect of the present disclosure that the garment panel 300 partially shown in
Therefore, in accordance with aspects herein, a plurality of perforations 450 can be provided at the seams securing/joining at least the first and the second layers of pliable material together, where the plurality of perforations 450 are shown on each of the seams 410, 430, and 440, and extend through the first layer and the second layer of pliable material to form a two-way passage between an environment internal to the garment and an environment external to a formed garment when the garment is worn by a wearer. The seams 410, 430, and 440 may, for example, be formed by sewing along a top margin and a bottom margin defining the respective seam 410, 430, or 440, or alternatively, the seams 410, 430, and/or 440 may be formed by adhering internal surfaces of both garment layers together using an adhesive tape having a particular width, and/or, the seams 410, 430, and/or 440 may be formed by adhering/fusing the garment layers together with or without an adhesive, depending on the type of material used for the garment layers. In addition to adhering/fusing the garment layers together, there may be stitching added along one or both seam boundaries 412, 414, 432, 434, 442, and 444 for each seam 410, 430, and 440 respectively. Any and all aspects, and any variation thereof, are contemplated as being within aspects herein.
In the exemplary view of the partial panel 400 shown in
Alternatively, as shown on seam 430, only a discrete number of perforations 450 may be provided on and through the seam 430, depending on the location of the seam 430 on a formed garment. To put it another way, instead of extending along the length of the seam as with the seam 410, perforations 450 may be formed on only a portion of the seam 430. Similar to seam 410, seam 430 comprises a first/upper seam boundary 432 and a second/lower seam boundary 434, with the one or more perforations 450 being provided within the seam boundaries 432 and 434.
In yet a different example, as shown in seam 440, the one or more perforations 450 may be provided intermittently along the length of the seam 440 to form a repeating pattern. The one or more perforations 450 extend through the seam 440 and are located within a first/upper seam boundary 442 and a second/lower seam boundary 444 of the seam 440. The garment in accordance with aspects herein, may comprise multiple baffles in each garment panel. For example, the lower seam boundary 434 of seam 430 and the upper seam boundary 442 of seam boundary 440, may define baffle 407, also enclosing multiple voided portions 420 in the layer of thermally insulating sheet material, within the baffle 407.
In exemplary aspects, the seams 410, 430, and 440 may be spaced apart in a generally horizontal orientation on the partial panel 400 as shown in
Continuing, in some aspects, the seams 410, 430, and 440 may be spaced such that there is minimal space between the seams 410, 430, and 440 thereby resulting in smaller-sized baffles 405 and 407. In other aspects, the seams 410, 430, and 440 may be spaced more widely apart to create larger-sized baffles 405 and 407 with the ability to enclose more voided portions 420 of the layer of thermally insulating sheet material. In some exemplary aspects, spacing between the seams 410, 430, and 440 may be greater than the width of the seams 410, 430, and 440 (defined by first and second seam boundaries of each seam). In other exemplary aspects, spacing between the seams 410, 430, and 440 may be greater than twice the width of the seam 410, 430, and 440, and so on. Exemplary distances between adjacent seams 410, 430, and 440 may comprise, for example, between 1 cm and 20 cm, between 2 cm and 15 cm, and/or between 3 cm and 10 cm, although ranges above and below these values are contemplated herein. In aspects, the spacing between adjacent seams 410, 430, and 440 may be variable depending upon the desired amount of insulation needed at different portions of a garment. In other words, smaller baffles (seams are closer together) may be able to enclose a thinner, or a smaller section of thermally insulating sheet material when compared to a larger baffle (seams are further apart). Further, the seams 410, 430, and 440 may be linear, as shown, or alternatively, the seams 410, 430, and 440 may take on a non-linear, or in other words, a curvilinear configuration (not shown).
Further, as described above, the perforations 450 may form a pattern on the seams 410, 430, and 440. The seams 410, 430, and 440 may be perforated to form the one or more perforations 450 when the seams 410, 430, and 440 are being formed, or the perforations 450 may be created after the seams 410, 430, and 440 are formed. In exemplary aspects, one or more perforations 450 in the seams 410, 430, and 440 may be formed using, for instance, a laser, an ultrasonic cutter, a water-jet cutter, a mechanical cutter, and the like. Provided the proper equipment, the seams 410, 430, and 440 may be simultaneously formed and perforated in a single step to form the one or more perforations 450, although the seams 410, 430, and 440 and the one or more perforations 450 may be formed in separate steps without departing from the scope of the technology described herein. In other aspects, the one or more perforations 450 may be integrally formed in the seams 410, 430, and 440 during a knitting or a weaving process, as shown in
With respect to
Moving on to
In exemplary aspects, the one or more vent openings 422 may have a similar shape as the voided portion 420 in the thermally insulating sheet material, as shown, or may have a shape that is different than the voided portion 420, as shown in, for example, vent openings 423, 424, and 425. Alternatively, multiple vent openings may be formed at a single affixed portion 480 (delineated by margin 428), as shown for vent openings 426 and 427.
With reference to both
In accordance with aspects herein, each panel 522a, 522b, and 520 of, for example, upper body garment 500 may be formed to be an insulated garment panel comprising at least one layer of thermally insulating sheet material having one or more voided portions interposed or positioned between at least two layers of pliable sheet material in all panels 522a, 522b, and 520 of the garment 500 (in this configuration, the entire garment 500 will have the configuration of the garment areas 540 shown in
Continuing, the garment areas 530 may comprise the same materials as the garment areas 540 minus the thermally insulating sheet material layer, i.e. having the interior and exterior pliable material garment layers extending throughout the panels 522a, 522b, and 520 through garment areas 530 with the thermally insulating sheet material layer only being present in garment areas 540.
Alternatively, the garment areas 530 may comprise the same materials as the garment areas 540 with the thermally insulating sheet material layer affixed to only the interior garment layer in the garment areas 530 (via tack points (adhesive or stitched) or stitching lines along portions of the interior garment layers aligning with non-voided portions 594 of the thermally insulating sheet material). Garment areas 540, on the other hand, may have the thermally insulating sheet material layer affixed to both the interior and the exterior garment layers, or affixed to just the exterior garment layer via seams 555 formed by, for example, stitching along portions of the internal and external garment layers that align with non-voided portions 594 of the thermally insulating sheet material. This configuration allows for the formation of a visual effect, minimizing the appearance of seams 555 formed by, for example, stitching, on the outer surface of the upper body garment 500.
Moreover, in yet another example of the upper body garment 500, the garment areas 530 may comprise a single layer of material, for example, the same material as the exterior garment layer, where the garment areas 540 and 530 may be part of the same exterior garment panel (seamless transition between garment areas 540 and 530). Alternatively, the garment areas 530 may comprise a single layer of material, for example, the same material as the interior garment layer, where the garment areas 540 and 530 may be part of the same interior garment panel (seamless transition between garment areas 540 and 530).
Furthermore, in yet another example of the upper body garment 500, the garment areas 530 may comprise one or more layers of different materials than the materials forming the garment areas 540. For example, garment areas 540 may comprise external and/or internal garment layers formed from, for example, an ultra-thin fabric/textile optionally treated with a DWR chemical treatment. Further, garment areas 540 may comprise a thermally insulating sheet material having one or more voided portions 550 interposed or positioned between the external and internal garment layers. The garment areas 530, on the other hand, may be formed of a breathable and elastic moisture management knit or woven textile, a mesh fabric, a cotton fabric, a terry fabric, or any other suitable fabric in accordance with aspects herein. In accordance with aspects herein, the garment areas 530 may be comprised of one or more breathable garment panels 532 and the garment areas 540 may be comprised of one or more insulated garment panels 542. In the example shown in
As described above, the garment areas 540 may comprise at least one interior layer and at least one exterior layer of pliable material with a layer of thermally insulating sheet material having a plurality of voided portions 550, interposed or positioned between the at least one interior layer and the at least one exterior layer of pliable material. The layer of thermally insulating sheet material in upper body garment 500 is secured to at least the exterior layer of pliable material (i.e. could be secured to both the interior and the exterior layers of pliable material) via a plurality of seams 555 formed at portions on the interior and exterior layers of pliable material corresponding to non-voided portions 594 in the layer of thermally insulating sheet material. The plurality of seams 555 cooperate with each other to form a plurality of baffles 516. Each baffle 516 in this example, encloses a corresponding voided portion 550 defined by a perimeter 560 in the layer of thermally insulating sheet material. Further, as shown, the upper body garment 500 comprises one or more of affixed portions 582 where the interior surface of the interior layer of pliable material is affixed to the interior surface of the exterior layer of pliable material in areas corresponding to one or more voided portions 550 in the thermally insulating material, each affixed portion 582 being defined by a perimeter 580. Each affixed portion 582 defined by a perimeter 580 may then be perforated or otherwise opened up or cut to accommodate vent openings 570, each vent opening 570 being defined by a perimeter 572. The vent openings 570 may be strategically placed throughout the upper body garment 500 at areas on the upper body garment 500 aligning with a wearer's body parts that produce the greatest amount of heat and perspiration for cooling (for example: armpits, upper back, lower back, chest, thighs, and the like). Depending on the type of garment and the amount of coverage offered by the particular garment, the vent openings 570 may be placed throughout a garment to add a visual effect by forming a pattern with the vent openings 570, in addition to providing ventilation to the garment.
In accordance with aspects herein, each panel 602 and 604 of, for example, upper body garment 600 may be formed to be an insulated garment panel comprising at least one layer of thermally insulating sheet material having one or more voided portions 622 interposed or positioned between at least two layers of pliable sheet material in all panels 602 and 604 of the upper body garment 600. Alternatively, different types of materials may be combined to create a final garment having different characteristics at different areas of the upper body garment 600. For example, the back panel 604 may have a first area 630 and a second area 632, as shown in
Each of the seams 616 may have a first seam boundary 616a and a second seam boundary 616b that define the width of each seam 616. As shown in
Stitching along the first seam boundary 616a and the second seam boundary 616b of the seams 616 may be optional for reinforcement when the garment layers are adhesively bonded or fused together. If the seams 616 are only formed by stitching, the plurality of perforations 618 may extend straight through both garment layers at the seams 616, or a plurality of perforations on the interior garment layer (not shown) may be offset from the plurality of perforations 618 on the exterior garment layer. When the plurality of perforations on the interior garment layer are offset from the plurality of perforations 618 on the exterior garment layer, air or moisture may flow from the plurality of perforations on the interior garment layer through a passage formed between the interior and exterior garment layers at the seams 616, and out through the plurality of perforations 618 on the exterior garment layer. As well, cool air may enter the upper body garment 600 through the plurality of perforations 618 on the exterior garment layer, through the passage formed between the interior and exterior garment layers at the seams 616, and into the garment through the plurality of perforations on the interior garment layer. The plurality of perforations 618 may be formed in accordance to any configuration, for example, as described with respect to
The thermally insulating sheet material interposed or positioned between the interior and the exterior garment layers may be shaped according to the specifications of a particular garment panel to fit within a desired cavity/baffle formed by the interior and exterior garment layers in the panels 602 and 604. For example, as shown in
As shown, the thermally insulating sheet material may comprise the one or more voided portions 622 only in certain areas of the garment 600, and may be free from voided portions in other areas such as, non-voided portions 640 of the garment. For example, in the upper body garment 600, only the upper three-quarters of the upper body garment 600 comprises the one or more voided portions 622 in the thermally insulating sheet material. Alternatively, the upper body garment 600 may comprise different areas of the garment panels with different material constructions, such as, for example, areas 630 and 632 in the back panel 604. For instance, the garment areas 632 may comprise the same materials as the garment areas 630 minus the thermally insulating sheet material layer (i.e. having the interior and exterior pliable material garment layers extending throughout the garment in areas 632 with the thermally insulating sheet material layer only being present in garment areas 630). Moreover, in yet another aspect, the garment areas 632 may comprise different materials than the garment areas 630. For example, the garment areas 632 may be formed of a breathable and elastic moisture management knit or woven textile, a mesh fabric, a cotton fabric, a terry fabric, or any other suitable fabric in accordance with aspects herein.
As shown, the upper body garment 600 in this example, comprises four “baffles,” each baffle enclosing a plurality of voided portions 622 defined by perimeters 620 in the layer of thermally insulating sheet material. Further, as shown, the upper body garment 600 comprises one or more affixed portions 660 in the back panel 604, where the interior surface of the interior garment layer is affixed to the interior surface of the exterior garment layer at areas corresponding to one or more voided portions 622 in the thermally insulating material, each affixed portion 660 being defined by perimeter 624. Each affixed portion 660 defined by a perimeter 624 may then be cut or otherwise manipulated to form vent openings 628, each vent opening 628 being defined by a perimeter 626. The vent openings 628 may be strategically placed throughout the upper body garment 600 at areas on the upper body garment 600 aligning with a wearer's body parts that produces the greatest amount of heat and perspiration for rapid cooling (for example: armpits, upper back, lower back, chest, thighs, and the like depending on the type of garment and the amount of coverage offered by the particular garment). Alternatively or additionally, the vent openings 628 may be placed throughout the upper body garment 600 to add a visual effect by forming a pattern with the vent openings 628. For example, the plurality of vent openings 628 in
As seen in
Sleeve 710 of garment 700 illustrates an exemplary configuration for the voided portions 720 shown by the dashed lines 722 in the thermally insulating sheet material. As shown, the voided portions 720 may comprise any shape and size. In this particular example, the voided portions 720 comprise a curvilinear organic shape. The thermally insulating sheet material may be secured to the outer garment layer, the inner garment layer, or both the inner and the outer garment layers. For example, the thermally insulating sheet material may be secured to the outer garment layer or both the outer and inner garment layers through one or more tack points or stitches 730 to minimize the appearance of stitching, as shown. However, the tack stitches or points 730 may have also been made to secure the thermally insulating sheet material to only the inner garment layer, as is the case for seams 740 shown by dashed lines to indicate that the seams 740 are located interior to the outer garment layer. The seams 740 may be formed by any suitable means such as stitching, adhesive bonding, and the like.
Moving on to front panel 750, front panel 750 illustrates a different exemplary configuration for the plurality of voided portions 724 shown by dashed lines 726 in the thermally insulating sheet material in accordance with aspects herein. As seen in front panel 750, the plurality of voided portions 724 may comprise different sizes at different locations of the garment 700. In the particular example shown, the plurality of voided portions 724 comprise a curvilinear shape that forms a gradient 760 with the largest voided portion 724 starting at the middle and becoming increasingly smaller at the superior and inferior portions of the garment 700 with respect to the garment 700 being in an as-worn configuration. In addition to offering insulation, this type of configuration for the plurality of voided portions 724 may add a visual appeal to the garment 700 when at least the outer garment layer is made to be transparent or translucent, thereby allowing the viewing of the voided portions 724 in the thermally insulating sheet material. Additionally, in order to reduce the appearance of seams, the thermally insulating sheet material may be secured to the inner and/or outer garment layers only at the garment forming seams.
Turning to front panel 752, front panel 752 shows yet another exemplary configuration for the plurality of voided portions 729 in the thermally insulating sheet material shown by dashed lines 728. As shown in the front panel 752, a gradient in size 762 of the voided portions 729 may be created, where the voided portions 729 comprise geometric shapes in the form of squares or rectangles. Further, as illustrated by the gradient in size 762, the size of the plurality of voided portions 729 may be varied according to particular specifications for the garment 700 such as, for example, the level of insulation desired, the visual effects desired, and the like. Thus, garment 700 illustrates a few of the numerous possibilities for garment configurations in accordance with aspects herein. Additionally, although not explicitly shown here, one or more vent openings may be optionally provided at locations on the garment 700 corresponding to one or more voided portions 720, 724, or 729 to provide ventilation by aiding in air circulation in and out of the garment 700.
The insulation sections 802, 804, 806, 808, 810, and 812 can be installed within the garment 800 by, for instance, cutting out portions of the garment 800 and inserting the insulation sections 802, 804, 806, 808, 810, and 812 in place of the cutout areas, or the insulation sections 802, 804, 806, 808, 810, and 812 may be placed adjacent to and joined to an outer surface of the garment 800. This will become more apparent in the cross-sectional view 900 along the line 9-9 of the left garment panel 816 of garment 800, as shown in
Turning now to
Continuing, one or more affixed portions 832 may be formed at different locations on the insulation sections 804 and 812 by joining (using an adhesive, fusing, welding, and the like) an interior surface 904 of the first layer 902 to an interior surface 910 of the second layer of pliable material 908 at areas on the first layer 902 and second layer 908 of pliable material aligning with a corresponding voided portion 828 in the thermally insulating sheet material 918/920. Each affixed portion 832 in the insulation sections 804 and 812 further comprises a vent opening 814 that extends through the first layer 902 and the second layer 908 of pliable material. The vent openings 814 allow heat and moisture that may buildup underneath the insulation sections 804 and 812 when the garment 800 is worn, to escape into the environment external to the garment 800. Additionally, the vent openings 814 may allow cooler air from the external environment to enter an environment internal to the garment 800 to regulate the internal temperature and prevent overheating especially, as the level of physical exertion of a wearer increases with exercise intensity and/or time.
As exemplified in
Furthermore, the garment base layer 834 may comprises a plurality of interior perforations or openings (not shown). The plurality of interior openings may not directly communicate with the external environment in contrast to the vent openings 814 on the affixed portions 832 of the insulation sections 802, 804, 810, and 812. The plurality of interior openings on the garment base layer 834 may be configured such that the plurality of interior openings are offset from the vent openings 814 on the insulation sections 802, 804, 810, and 812. In other words, there is not a direct communication path between the vent openings 814 and the plurality of interior openings. To put it another way, the route that moisture vapor and/or air would traverse when traveling through the garment 800 is not direct (straight), namely: the moisture vapor and/or air would traverse 1) from the wearer's body, 2) through the plurality of interior openings, 3) into the space 922, and 4) out the vent openings 814 where the moisture vapor may be discharged into the external environment.
The plurality of interior openings in the garment base layer 834 may be distributed throughout the garment base layer 834 and/or may be localized in certain areas such as only underneath the insulations sections 802, 804, 810, and 812, depending on the level of ventilation and/or breathability needed for the garment 800. In one exemplary aspect, the plurality of interior openings on the garment base layer 834 may be configured to overlap with the vent openings 814. In another exemplary aspect, the plurality of interior openings on the garment base layer 834 may be configured to not overlap with the vent openings 814 associated with the insulation sections 802, 804, 810, and 812 at all. In another exemplary aspect, the distribution of the plurality of interior openings on the garment base layer 834 may be configured such that a majority of the plurality of interior openings (e.g., greater than 50%, 70%, 80%, or 90%) do not overlap with the vent openings 814.
The size and number of the vent openings 814 on the insulation sections 802, 804, 810, and 812, and/or the plurality of interior openings (not shown), may be adjusted to provide different ventilation and breathability characteristics, while still maintaining the structural integrity of the fabric and the thermally insulating sheet material 918/920. For instance, a larger size and/or greater number of vent openings 814 in portions of the garment 800 may provide a higher degree of ventilation and breathability characteristics to these portions. In another example, a smaller size and/or a fewer number of vent openings 814 in other portions of the garment 800 may provide for a lower degree of ventilation and breathability characteristics. Thus, by adjusting the size and/or number of the vent openings 814, different ventilation and breathability characteristics may be imparted to different portions of the garment 800. In exemplary aspects, the width size of each individual vent opening 814 may range anywhere from 0.1 mm to 20 mm, between 0.1 mm and 15 mm, between 1 mm and 10 mm, between 2 mm and 5 mm, and the like. Other sizes of vent openings 814 may be used without departing from the scope of the technology described herein.
Furthermore, as briefly described above, the level of insulation may be adjusted by providing more or less insulation in the different insulation sections 802, 804, 806, 808, 810, and 812. For instance, as seen in
Turning now to
The construction of a garment, for example, as shown in garment 1000, will increase comfort for a wearer as the need for layering multiple garments together may be eliminated by providing thermal insulation to only those areas in the garment configured to cover thermally sensitive or most exposed areas of the wearer's body that would benefit from having a thermally protective layer. Another advantage of a garment construction with zonal thermal insulation such as garment 1000 is that there is no bulkiness impeding motion (as in conventional thermally insulated garments) and therefore, the wearer is afforded to have greater range of motion.
Moving on to
Aspects are not limited to these locations or functions. For example, the insulation sections 1202, 1204, 1206, 1208, 1210, 1212, 1214, and 1216 may be located in other desired/suitable locations within the pants 1200. Further, as shown, the insulation sections 1202, 1204, 1206, 1208, 1210, 1212, 1214, and 1216 may comprise different configurations, further allowing for the customization of the thermal function and the aesthetic appeal of the pants 1200 by customizing the different insulations sections 1202, 1204, 1206, 1208, 1210, 1212, 1214, and 1216 used throughout the pants 1200.
Turning now to
Turning now to
In one aspect, one or more portions of the insulated garment may be constructed using an engineered weaving or knitting process (e.g., program a weaving or knitting machine to form these structures). For example, the exterior panels and the interior panels may be formed together through the knitting and weaving process, where the knitting or weaving process may be used to form the seams and/or the exterior and interior openings.
Optionally, if venting is desired for the garments in accordance with aspects herein, one or more vent openings may be formed by bonding a first portion of an interior surface of the first layer of pliable material and a corresponding second portion of an interior surface of the third layer of pliable material that are in alignment with at least one voided portion in the one or more voided portions of the second layer of thermally insulating sheet material to form at least one affixed portion. Then, one or more vent openings may be formed at the affixed portion that extend through all layers of the affixed portion. Alternatively, the ventilation may be provided at one or more seams separating one or more baffles of a garment/pod constructed in accordance with aspects herein. The one or more seams separating the one or more baffles may comprise a width defined by seam boundaries/edges for each of the one or more seams. The one or more seams may be formed in a similar manner as the affixed portions described above, where an interior surface of the first layer of pliable material and a corresponding interior surface of the third layer of pliable material are affixed by welding, adhesive bonding and the like, along a length of the one or more seams. Alternatively, the one or more seams may be formed by stitching first and second seam boundaries for each of the one or more seams (thereby defining a width for each seam in the one or more seams), or the one or more seams may be integrally formed in a weaving or knitting process.
Once the one or more seams separating one or more baffles of a garment/pod are provided, the one or more seams may be perforated by laser cutting, die cutting, or any other suitable method, to form a plurality of perforations on and through the one or more seams. Alternatively, the plurality of perforations may be integrally formed in the knitting or weaving process, when the one or more seams are formed in the process of forming the garment panels. Any and all aspects, and any variation thereof, are contemplated as being within the scope herein.
Advantages of Providing Garments with Vent Openings:
As described above, garments constructed in accordance with aspects of the present invention may comprise vent openings that allow an environment internal to the garment to be in communication with an environment that is external to the garment by allowing a two-way airflow through the vent openings, thereby allowing a wearer of the garment to keep a comfortable level of protection throughout, for example, an entire workout. In other words, the vent openings allow the wearer to wear the insulated garment comfortably without overheating.
Therefore, the number of vent openings, the size of the vent openings, and the location of the vent openings may have an effect on the performance of the garment in keeping a balance between cooling down a wearer by allowing heat and moisture to escape through the vent openings and providing insulation in cold weather. For example, when comparing, for example, a first insulated garment comprising 0 (no) vent openings with an insulated garment comprising, for example 18 vent openings distributed throughout, the addition of vent openings may not affect the insulation properties of the garment but may have a positive effect in improving (i.e., decreasing) the evaporative resistance of the garment once vent openings are introduced to the garment because the vent openings may improve ventilation to effectively allow moisture vapor to vent out of the garment.
The aspects described throughout this specification are intended in all respects to be illustrative rather than restrictive. Upon reading the present disclosure, alternative aspects will become apparent to ordinary skilled artisans that practice in areas relevant to the described aspects without departing from the scope of this disclosure. In addition, aspects of this technology are adapted to achieve certain features and possible advantages set forth throughout this disclosure, together with other advantages which are inherent. It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations. This is contemplated by and is within the scope of the claims.
Since many possible embodiments may be made of the technology described herein without departing from the scope thereof, it is to be understood that all matter herein set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.
This application entitled “Insulated Garment,” claims the benefit of priority of U.S. Provisional Application No. 62/404,966, entitled “Insulated Garment,” and filed Oct. 6, 2016. The entirety of the aforementioned application is incorporated by reference herein.
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Number | Date | Country | |
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20180098588 A1 | Apr 2018 | US |
Number | Date | Country | |
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62404966 | Oct 2016 | US |