阅读说明：本技术 应急呼吸系统的罩组件 (Hood assembly for emergency breathing system ) 是由 罗伯特·凯尔·富勒顿 西尔维娅·盖乔娃-博罗沃娃·古特曼 罗伯特·D·威廉姆斯 斯科特·M·普 于 2020-04-30 设计创作，主要内容包括：一种适配在使用者的头部上的呼吸系统罩组件,该罩组件包括不透气罩,该不透气罩具有尺寸被设计成适配在使用者的头部上的开口和沿开口的至少一部分布置的能弹性变形的颈部密封件。颈部密封件包括其中颈部密封件被布置成与自身成重叠关系的区域,由此颈部密封件能够膨胀以适配在使用者的头部上并且收缩以与所述使用者的颈部形成密封。(A respiratory mask assembly that fits over a user's head, the mask assembly comprising an air-impermeable mask having an opening sized to fit over the user's head and an elastically deformable neck seal disposed along at least a portion of the opening. The neck seal includes a region in which the neck seal is arranged in overlapping relationship with itself, whereby the neck seal is expandable to fit over a user's head and to contract to form a seal with the user's neck.)

1. A respiratory mask assembly that fits over a user's head, the mask assembly comprising:

an air-impermeable cover having an opening sized to fit over the user's head; and

an elastically deformable neck seal disposed along at least a portion of the opening;

wherein the neck seal comprises an area in which the neck seal is arranged in overlapping relationship with itself, whereby the neck seal is expandable to fit over a user's head and contracted to form a seal with the user's neck.

2. The hood assembly of claim 1, wherein said neck seal has a unitary construction.

3. The hood assembly of claim 1, wherein said neck seal has an at least two-piece construction.

4. The cover assembly of claim 1, wherein the overlap region is attached to itself by at least one of stitching, adhesive, welding, or mechanical fasteners.

5. The hood assembly of claim 1, wherein said neck seal is folded onto itself, thereby forming a first portion and a second portion arranged in a partially overlapping relationship.

6. The hood assembly of claim 1, wherein said neck seal is twisted onto itself in overlapping relation, thereby forming a first portion and a second portion arranged in partially overlapping relation.

7. The shroud assembly of claim 5 or 6, wherein the first portion and the second portion are arranged to form an angle facing away from the air-impermeable shroud of at least about 80 degrees and not greater than about 110 degrees.

8. The hood assembly of claim 1, wherein said neck seal comprises at least one pair of elastic bands.

9. The hood assembly of claim 1, wherein said neck seal comprises an elastic band formed from a thin wide strip of material.

10. The hood assembly of claim 9, wherein said elastic band has a length of at least about 0.25 inches and a width of no greater than about 3.5 inches.

11. The hood assembly of claim 10, wherein said elastic band has a contracted half length of no greater than about 4 inches.

12. The hood assembly of claim 11, wherein said elastic band is reversibly expandable to a half-length of at least about 11 inches.

13. The hood assembly of claim 12, wherein the force required to elongate a 1.5 inch wide elastic band by 3.5 inches is no greater than about 10 newtons.

14. The hood assembly of claim 13, wherein said elastic band has an elongation of at least about 50% and not greater than about 200%.

15. The hood assembly of claim 1, wherein a neck seal having an overlapping region has an elongation at least about 5% greater than a neck seal having no overlapping region.

16. The hood assembly of claim 1, wherein said neck seal comprises a fabric material.

17. The hood assembly of claim 16, wherein said fabric material comprises a woven fabric.

18. The hood assembly of claim 17, wherein said fabric comprises a polymer.

19. The hood assembly of claim 1, incorporated into at least one of a self-contained breathing apparatus (SCBA), a powered air purifying breathing apparatus (PAPR), an emergency escape breathing apparatus (EEBD), and an air purifying breathing Apparatus (APR).

20. The hood assembly of claim 1, wherein said neck seal is attached to said air-impermeable hood along an entire perimeter of said opening.

Background

The present invention relates generally to emergency breathing devices and, more particularly, to a mask assembly for an emergency breathing device.

Emergency escape breathing apparatus (EEBD) is a personal emergency breathing system for escaping a hazardous or toxic environment. Such devices are designed to provide breathable air for a period of time sufficient to allow individuals to evacuate the hazardous environment and reach a safe location where the air is safe to breathe. EEBDs typically include several major components, including a supply of breathable air, at least one pressure regulator, a hose, and a mask that may be disposed over the head of a wearer.

Disclosure of Invention

Accordingly, there remains a need to improve the performance and use of emergency breathing systems. In particular, it has been desirable to have a hood assembly for an emergency breathing system that is comfortable, accommodates a wide range of head and neck sizes, and can be worn quickly and easily (e.g., in one step). The present disclosure generally provides an emergency breathing system, such as an emergency escape breathing apparatus (EEBD), that includes, for example, a supply of breathable air, a pressure regulator, and a mask assembly.

In one embodiment, the present invention provides a respiratory mask assembly that fits over the head of a user, wherein the mask assembly comprises an air-impermeable mask having an opening sized to fit over the head of a user, and further comprising an elastically deformable neck seal disposed along at least a portion of the opening, wherein the neck seal comprises a region in which the neck seal is disposed in overlapping relationship with itself, thereby defining an overlapping region, whereby the neck seal can be stretched or expanded to fit over the head of a user, and the neck seal can also be contracted to form a seal with the neck of a user.

In various embodiments and aspects, the neck seal may have a unitary or one-piece construction, the neck seal may have at least a two-piece construction, the overlap region may be attached to itself by at least one of stitching, adhesive, welding (e.g., ultrasonic welding), or mechanical fasteners, the neck seal may be folded onto itself to form a first portion and a second portion arranged in a partially overlapping relationship, the neck seal may be twisted onto itself in an overlapping relationship to form a first portion and a second portion arranged in a partially overlapping relationship, the first portion and the second portion may be arranged to form an acute angle, the first portion and the second portion may be arranged to form an obtuse angle, the first portion and the second portion may be arranged to form an angle away from the gas-impermeable shell of at least about 80 degrees and not greater than about 110 degrees, the neck seal may include at least a pair of elastic bands, the elastic bands may be formed of the same or different materials, and the neck seal may comprise an elastic band formed from a thin, wide strip of material, the elastic band may have a width of at least about 0.25 inches and a width of no greater than about 3.5 inches, and the elastic band may have a half-length to contract of no greater than about 4 inches. The elastic band is capable of reversibly expanding to a half length of at least about 11 inches, the force required to elongate a 1.5 inch wide elastic band by 3.5 inches may be no greater than about 10 newtons, the elastic band may have an elongation of at least about 50% and no greater than about 200%, the neck seal with the overlap region may have an elongation of at least about 0.5 inches greater than the neck seal without the overlap region, the neck seal with the overlap region may have an elongation of at least about 5% greater than the neck seal without the overlap region, the neck seal may include a fabric material, the fabric material may include a woven fabric, the fabric may include at least one of polyester, latex elastomer, rubber, nylon, polyamide, cotton, and combinations thereof, the air impermeable cover may include a transparent synthetic plastic material, and the cover assembly may be incorporated into a self-contained breathing apparatus (SCBA), In at least one of a Powered Air Purifying Respirator (PAPR), an emergency escape breathing apparatus (EEBD), or an Air Purifying Respirator (APR), the hood assembly may include a port connectable to a supply of breathable air, which may be supplied by a compressed air cylinder, which may be filtered air, a supply of breathable air, which may be a chemical oxygen generator, which may automatically contract to form a seal around the neck of the user once the neck seal is pulled over the head of the user and released by the user, allowing the user to wear the hood assembly in a single step, and/or the neck seal may be attached to an air-impermeable hood along the entire perimeter of the opening (e.g., in one step).

Advantages of certain embodiments of the emergency breathing system described herein include providing a hood assembly that is easy to manufacture and use, affordable, comfortable, adaptable to a variety of head and neck sizes, and easy to wear.

Drawings

Fig. 1 is a perspective view of an emergency breathing system including a hood assembly according to an embodiment of the present invention.

Fig. 2 is a diagrammatic, schematic view of a user wearing the emergency breathing system of fig. 1.

Fig. 3 is a plan view of a cover assembly according to a first embodiment of the present disclosure.

Fig. 4 is a plan view of a cap assembly according to a second embodiment of the present disclosure.

Fig. 5 is a detailed plan view of the first resilient neck seal in an intermediate or pre-assembled state prior to combination with the closure.

Fig. 6 is a detailed plan view of the second resilient neck seal in an intermediate or pre-assembled state prior to combination with the closure.

Fig. 7 is a plan view of the elastic neck seal of embodiment a with 60 degree overlap.

Fig. 8 is a plan view of the resilient neck seal of embodiment B with a 90 degree overlap.

Fig. 9 is a plan view of the resilient neck seal of embodiment a with 120 degree overlap.

FIG. 10 is a plan view of the resilient neck seal of embodiments A-T having an angular twist of about 60 degrees.

FIG. 11 is a plan view of the resilient neck seal of embodiment B-T with an approximately 90 degree angular twist.

FIG. 12 is a plan view of the resilient neck seal of embodiment C-T with an angular twist of about 120 degrees.

Fig. 13 is a plan view of the resilient neck seal of embodiment CS without an overlap or twist angle.

FIG. 14 is a graph of maximum force versus overlap angle for different elastic belts made using different manufacturing processes and raw materials.

FIG. 15 is a graph of performance gain (in percent) versus overlap angle (in degrees) for different elastic bands made using different manufacturing processes and raw materials.

Fig. 16 is a graph of maximum force versus overlap angle for four different overlap and twist angles.

Figure 17 is a graph of performance increase (in percent) versus overlap angle (in degrees) for three different overlap and twist angles.

Detailed Description

Referring now to fig. 1 and 2, in which like reference numerals designate like or corresponding parts, there is shown an emergency breathing system or emergency escape breathing apparatus (EEBD)2 including a canister or cylinder 4 of compressed breathable air, a regulator 6 and a flexible hose or tube 8 for delivering breathable air from the cylinder 4 to a hood assembly 10. The hood assembly 10 includes a hood 12 having an opening 14 with an elastically deformable neck seal 16 that is expandable to allow the hood 12 to be placed over a user's head 18 and collapsible to allow the neck seal 16 to be secured around a user's neck 20. Other aspects of the emergency breathing system are described in uk patent application GB2191950A (patent application 8615744-Glynn et al), the entire contents of which are hereby incorporated by reference.

The opening 14 in the hood 12 and the opening formed by the neck seal 16 are sized to accommodate (i.e., fit over) the head 18 of a user. Further, the neck seal 16 is configured to form a seal around the user's neck 20 to prevent, or at least significantly reduce, the possibility of hazardous or noxious gases or particulate matter from entering the protective space formed around the user's head by the hood 12.

In one aspect, the opening 14 and neck seal 16 are sized to accommodate a head having a circumference of at least about 17 inches, a circumference of at least about 18 inches, a circumference of at least about 19 inches, or a circumference of at least about 20 inches. In another aspect, the opening 14 and neck seal 16 are sized to accommodate a head having a circumference of no greater than about 25 inches, no greater than about 26 inches, no greater than about 27 inches, or no greater than about 28 inches. In another aspect, the neck seal 16 is sized to accommodate necks having a circumference of at least about 9 inches, at least about 10 inches, at least about 11 inches, or at least about 12 inches, and necks having a circumference of no greater than about 20 inches, no greater than about 21 inches, no greater than about 22 inches, or no greater than about 23 inches.

In the illustrated embodiment, the neck seal 16 includes a pair of overlapping regions 16a, 16b, wherein the neck seal 16 is disposed in overlapping relationship with itself. While the illustrated embodiment includes two overlapping regions, one at each of the opposite ends of the neck seal 16, it should be understood that the neck seal 16 may include only one overlapping region or it may include three or more overlapping regions. Further, in the illustrated embodiment, the elastic neck seal 16 is disposed along the entire periphery of the opening 14. However, it will be appreciated that the neck seal 16 may be disposed along a portion of the opening 14.

In accordance with one aspect of the present invention, it has been found that the overlap regions 16a, 16b improve the ability of the neck seal 16 to accommodate a wide range of head and neck sizes (i.e., large and small heads and necks). More specifically, the overlapping regions 16a, 16b improve the ability of the neck seal to expand and thereby fit over the user's head, and also improve the ability of the neck seal to contract and form a seal around the user's neck. That is, providing the neck seal 16 with at least one overlapping area increases the stretchability of the neck seal 16, allowing the neck seal 16 to accommodate a wide range of head sizes, while also allowing the neck seal 16 to be comfortably secured around the neck of the user in a manner that forms a suitable seal to protect the user from hazardous or toxic gases that may be present in the surrounding environment. Further, once the neck seal 16 is pulled over the user's head, it automatically forms a seal around the user's neck, whereby the mask assembly 10 can be worn by the user in a single step.

As detailed below, the neck seal 16 may have a unitary (i.e., one-piece) construction in which at least one overlap region 16a, 16b is formed by folding or twisting the neck seal 16 onto itself in an overlapping relationship, or the neck seal 16 may have an at least two-piece construction (i.e., a multi-piece construction) in which the overlap region is formed by arranging at least two separate or discrete strips of material secured or attached to one another in an overlapping relationship. The particular manner in which the strips are secured to one another is not important to the invention, so long as it provides the desired function. Suitable means for attaching the individual straps to one another include, for example, stitching, adhesives, welding, or mechanical fasteners (e.g., buckles, clips, clamps, buttons, snaps). Further, the overlap regions 16a, 16b may be formed such that portions of the neck seal 16 that extend outwardly in a direction opposite the overlap regions may be arranged at a selected angle.

In the illustrated embodiment, the mask assembly 10 includes a mask 12 that includes a large opening 14 at the bottom of the mask 12 that is sized to accommodate the head 18 and neck 20 of the end user, and also includes a small opening 24 or air connection port in the front of the mask 12 that is connectable to a supply of breathable air. In the embodiment shown, the breathable air is supplied by a compressed air cylinder 4 connected to a hood 12 via a hose 8. In other embodiments, the breathable air may comprise filtered air, or the breathable air supply may comprise a chemical oxygen generator.

In the illustrated embodiment, the cover 12 is formed of a gas impermeable material, such as a transparent synthetic plastic material. Suitable materials include, for example, polyurethane. Alternatively, it will be appreciated that the cover 12 may be formed from an opaque, air-impermeable material (e.g. woven or non-woven cloth or fabric material), and the cover 12 may be provided with a substantially transparent window through which the user can view the surrounding area.

An elastically deformable (i.e., reversibly stretchable and contractible) neck seal 16 is disposed along the opening 14. In the illustrated embodiment, the overlapping regions 16a, 16b of the neck seal 16 are generally disposed along the front and rear of the hood 12. That is, the overlapping regions 16a, 16b are arranged at about 180 degrees from each other at opposite ends of the neck seal 16. It will be appreciated that the overlap regions 16a, 16b may be disposed in different orientations relative to each other (e.g., at 90 degrees to each other) and at different positions relative to the shroud 12 (e.g., along the sides of the shroud 12 rather than along the front and rear of the shroud).

In one embodiment, the neck seal 16 comprises a fabric material. The fabric material may comprise, for example, a knitted or woven (e.g., twill) material. Suitable materials for the neck seal 16 include, for example, polyester, latex elastomers, rubber, and combinations thereof. In a particular embodiment, the neck seal 16 comprises at least one of neoprene and polyurethane elastic fibers (e.g., lycra).

Referring to fig. 3 and 4, fig. 3 shows a side view of the shroud assembly 10 shown in fig. 1 and 2, and fig. 4 shows a front view of the shroud assembly 10 shown in fig. 1 and 2. It will be appreciated that the reference to fig. 3 as a side view and fig. 4 as a front view is somewhat arbitrary. Fig. 3 is referred to as a side view because this is generally the manner in which the cover assembly 10 appears when the cover assembly 10 is worn by a user as intended and viewed from the side of the user (i.e., from the user's shoulders toward the user's ears). Similarly, fig. 4 is referred to as a front view, as this is generally the manner in which the mask assembly 10 appears when viewed from the front of the user (i.e., at the face of the user).

In the embodiment shown in fig. 3 and 4, the neck seal 16 comprises a pair of elastic bands 26, 28 formed from thin, wide strips of material. In the illustrated embodiment, each elastic band 26, 28 is formed of the same material. However, it will be appreciated that the or each strap 26, 28 portion may be formed of different materials.

In particular aspects, the neck seal 16 has a width of at least about 0.25 inches, at least about 0.5 inches, or at least about 1 inch. In another aspect, the neck seal 16 has a width of no greater than about 2 inches, no greater than about 2.5 inches, or no greater than about 3.5 inches.

As previously mentioned, the neck seal 16 is configured to accommodate a wide range of head and neck sizes. To this end, in certain embodiments, the neck seal 16 has a natural resting (i.e., contracted or unexpanded) half-length of no greater than about 4 inches, no greater than about 6 inches, no greater than about 8 inches, no greater than about 9 inches, or no greater than about 10 inches. Further, the neck seal 16 is capable of being elastically deformed (i.e., it can be stretched without breaking) to a half-length of at least about 11 inches, at least about 12 inches, or at least about 13 inches. The half length of the neck seal 16 refers to its length when flattened out so that the opposing sides can contact each other.

In embodiments where the neck seal 16 comprises a pair of elastic bands, each elastic band 26, 28 has a natural resting (i.e., contracted or unexpanded) length of no greater than about 4 inches, no greater than about 6 inches, no greater than about 8 inches, no greater than about 9 inches, or no greater than about 10 inches. Further, the neck seal 16 is capable of being elastically deformed (i.e., stretched without breaking and returning to its approximate original length) to a length of at least about 11 inches, at least about 12 inches, or at least about 13 inches.

Another way to characterize the extended or stretched dimension of the neck seal 16 is by its degree of elongation. Thus, in one aspect, the neck seal 16 can be elongated by at least about 50%, at least about 60%, or at least about 75%, and can be elongated by no greater than about 125%, no greater than about 150%, or no greater than about 200%. That is, by way of example, a neck seal 16 having a half length of 7 inches may be stretched to a half length of at least about 10.5 inches (i.e., 50%) to no greater than about 21 inches (i.e., 200%, meaning that the neck seal may be stretched to three times its original or unstretched length). Similarly, in embodiments in which the neck seal 16 includes a pair of elastic bands 26, 28, each elastic band can be elongated by at least about 50%, at least about 60%, or at least about 75%, and can be elongated by no greater than about 100%, no greater than about 150%, or no greater than about 200%.

In another characterizing aspect, the force required to extend the 1.5 inch wide elastic band used to form the neck seal 16 by 3.5 inches is no greater than about 10 newtons, no greater than about 20 newtons, or no greater than about 30 newtons. This range of stretching force is desirable because it allows the neck seal 16 to stretch easily to fit on the user's head, and also allows the neck seal 16 to form a comfortable seal with the user's neck (i.e., form an adequate seal but not be too tight).

In another characterizing aspect, the neck seal 16 having at least one overlap region 16a, 16b has an elongation that is at least about 5% greater, at least about 10% greater, at least about 15% greater, or at least about 20% greater than a neck seal without an overlap region. In particular embodiments, a neck seal 16 having at least one overlap region 16a, 16b that is about 7 inches in half length will have an elongation that is at least about 0.5 inches greater, at least about 1 inch greater, or at least about 1.5 inches greater than a neck seal that does not include an overlap region. In this way, the overlap region provides the neck seal 16 with additional elongation characteristics that enhance the neck seal's ability to accommodate a wider range of head and neck sizes.

Referring now to fig. 5, wherein features similar or analogous to those shown in fig. 1 and 2 are added by 100, there is shown an embodiment of a neck seal 116 in a pre-assembled state. That is, for ease of illustration, the neck seal 116 is shown unattached to the hood and the free ends of the neck seal 116 are not fastened together to form a loop or continuous ring or band. In the illustrated embodiment, the neck seal 116 comprises two separate strips of material arranged in an overlapping relationship, forming an overlapping region 116 a. More specifically, the neck seal 116 includes a pair of legs 116c, 116d arranged in an overlapping relationship and sewn together along a line 122. In the illustrated embodiment, the suture 122 is depicted as being curved, but it should be understood that the suture 122 may also be linear.

As described above, the neck seal 116 may be configured to have an overlap region that forms a desired angle. In the illustrated embodiment, the legs 116c, 116d are arranged to form an angle "a" of about 90 degrees. In other embodiments, the legs 116c, 116d may be arranged to form an acute or obtuse angle. In a particular embodiment, the legs 116c, 116d are arranged to form an angle away from the air impermeable cover 12 in a range from at least about 80 degrees to no greater than about 110 degrees.

Referring now to fig. 6, wherein features similar or identical to those shown in fig. 1 and 2 are added by 200, another embodiment of a neck seal 216 in a pre-assembled state is shown. In the embodiment shown in fig. 6, the neck seal 216 comprises a single strip of material folded or otherwise disposed in at least partially overlapping relation to form an overlapping region 216 a. Arranged in this manner, the strip includes a first portion 216c and a second portion 216d arranged in a partially overlapping relationship, thereby forming an overlap region 216 a. In this embodiment, it will be appreciated that the neck seal 216 may, but need not, be secured to itself in the overlap region 216 a.

In another embodiment, the neck seal 216 may be twisted to be disposed upon itself in an overlapping relationship, rather than folded upon itself along a clear fold line.

As with the embodiment shown in fig. 5, the neck seal 216 shown in fig. 6 may be configured to have an overlap region that forms a desired angle. In the embodiment shown in fig. 6, the first portion 216c and the second portion 216d are arranged to form an angle "B" of less than 90 degrees. In other embodiments, the first portion 216c and the second portion 216d may be arranged to form an angle of about 90 degrees or an obtuse angle. As with the embodiment shown in fig. 5, the first portion 216c and the second portion 216d may be arranged to form an angle away from the air impermeable cover 12 in a range from at least about 80 degrees to no greater than about 110 degrees.

It will be understood by those skilled in the art that various changes and modifications may be made to the invention described above without departing from the inventive concept. For example, personal emergency breathing systems have been described primarily in the context of emergency escape breathing apparatus (EEBD). However, it will be appreciated that the personal emergency breathing system may be incorporated into, for example, a self-contained breathing apparatus (SCBA), a powered air purifying breathing apparatus (PAPR), or an air purifying breathing Apparatus (APR). That is, it will be appreciated that the mask assemblies described herein may be incorporated into any respiratory system that would benefit from such mask assemblies. Thus, the scope of the present invention should not be limited to the structures described in this application, but only by the structures described by the language of the claims and the equivalents of those structures.

Test method

Test method for measuring elongation

Elongation was measured according to astm d5034 on an Instron model 5565, serial No. C2067 from Instron, Norwood, Massachusetts, nowood. As a result, the force in newtons at a given elongation is measured. During testing, a 100N load cell, 3.5 "gauge, 1" narrow fixture was used.

Method for preparing a sample

The NIOSH has specifications for maximum and minimum circumferences of head and neck sizes to ensure that all head and neck sizes are adapted to be worn easily and to form an adequate seal around the neck. According to the present disclosure, the design has a one-step donning procedure and accommodates the maximum head circumference for donning and the minimum neck circumference to form an adequate seal around the neck. It is believed that the seal around the neck is the most important dimension for the product to function properly. As described below, for an overlapping or twisted design, the inner edge of the elastomeric member is used as a comparative distance for an elastomeric member that does not have an overlap or twist, which forms a seal in the final constructed design.

The overlap described in the embodiments below is formed by stacking and overlapping two separate end pieces of the elastomeric component on top of each other or twisting one continuous piece to a preferred angleAnd (4) an angle. The final closed configuration is designed to have at least one overlap angle formed by one of the above methods or a combination thereof. All test samples used 3M applied to the end of the sample^TMThe material GM631 was held to guide the sample during testing into alignment with the grip edge to have a consistent distance and to prevent slippage during tensile testing on the Instron.

Example A

Example a describes a sample (fig. 7) with a 60 degree angular overlap, prepared by manually cutting and sewing two separate elastic pieces together. The overlapped samples were made from a 1.5 inch wide elastic, table 2. The two elastic pieces were manually cut into 4.75 inches lengths, table 1. The two ends of the two pieces are stacked on top of each other and the right piece is stacked on top of the left end with their inner edges creating a 60 degree angle. After overlapping the two pieces, the outer edges of the elastic pieces were joined with a curved stitch line (table 1) of defined radius to form a continuous outer edge. Suture was prepared from white thread commercially available under the trade designation "D-Core 31001" (cotton-coated polyester, 40 Tex (Tex)) from American co. effird LLC, Mt Holly, North Carolina, American firm, united states thread limited liability company. Stitching is performed using a single needle lockstitch machine with an automatic down trimmer commercially available under the trade designation "Mitsubishi LS 2-1780" from Mitsubishi Electric Corporation, Tokyo, Japan. After the two pieces were sewn together, the inner edge was measured and marked from the overlap point to 1.75 inches (table 1) and "3M" from 3M Company of saint paul, Minnesota was applied (3M Company, st. paul, Minnesota)^TMThe grip material GM631 ".

The overlap angle samples were tested according to the test method for measuring tensile strength as described above, wherein the maximum load (N) values and the variation from the control sample are given in table 3. Example 1A corresponds to fig. 7.

Example B

Example B was prepared as described in example a, with an angular overlap of 90 degrees (fig. 8), and then stitched, applied with a clip material and tested as described in example a.

Example C

Example C was prepared as described in example a, with an angular overlap of 120 degrees (fig. 9), followed by stitching, application of the gripping material, and testing as described in example a.

Examples A to T

Examples a-T describe samples with 60 degree angular twist (fig. 10) prepared by manually cutting an elastic piece and pressing them together. The twisted samples were made from 1.5 inch wide elastomeric parts, table TT. The elastic was manually cut into 8.25 inches lengths, table 1. Both ends of the one-piece elastic were twisted, right side on top of left side with their inner edges angled at 60 degrees, then stitched, applied with a grip material and tested as described in example a.

Examples B to T

Examples B-T were prepared as described in examples a-T, with a 90 degree angular twist (fig. 11), followed by stitching, application of the gripping material, and testing as described in example a.

Examples C to T

Examples C-T were prepared as described in examples a-T, with an angular twist of 120 degrees (fig. 12), after which stitching, application of a clip material, and testing were performed as described in example a.

Example CS

Example CS (comparative sample) describes a sample with no overlap or twist and zero angular reference (fig. 13) prepared by manually cutting 1 elastic piece, after which a grip material is applied and tested as described in example a.

TABLE 1 sample size

Table 2-material content and manufacturer information

FIG. 14 is a diagram showing a series of elastic bands made at constant width and length using different manufacturing processes and stock materials (Table 2). In this figure, the trend of the maximum force required to elongate an embodiment at a constant distance shows the improvement in force reduction for any overlapping angle design (60 degrees, 90 degrees, 120 degrees angle) compared to a comparative flat sample of the same elastic belt (no-180 degree angle), table 3. Furthermore, in the case of an acute overlap angle, there is a reduction in force compared to an obtuse overlap angle. This reduction and the required force are not the same for all types of elastic material. The reduction in force results from the overlap or twist in the elastic band regardless of the material or method of making the elastic band.

Fig. 15 is a graph, table 4, showing different preparation methods (including overlapping or twisting) compared to a comparative flat sample. The examples show an improvement in force reduction regardless of the method of preparation, compared to comparative samples that do not include twisting or overlapping. Furthermore, the overlapping method of preparing samples shows an improvement in force reduction over certain angular ranges compared to the torsion method of preparation.

The test results indicate that the inner and outer edge distances, the overlap angle, and the elastomeric raw material and manufacturing process (tables 1 and 2) of the elastomeric design are parameters that affect the overall design performance. Based on this result, the preferred method of manufacture is by forming an overlap with two elastic members formed by a knitting manufacturing process, see FIGS. 15-19. In one embodiment, a knitted elastic component having a width of 1.5 inches and an overlap angle in the range of 90-120 degrees is used.

TABLE 3

The maximum force to extend an elastic made in different ways at a constant width of 1.5 inches and an extension distance of 3.5 "was compared for a straight elastic with 3 different overlap angles.

FIG. 15 shows the results of an elongation test comparing the increased performance in% with the overlap angle of different elastic components

TABLE 4

The maximum force to elongate an elastic made by overlapping and twisting was compared for a straight elastic and 3 angles.