The present invention relates to resistance garments having integral seamless resistive zones.
Resistance garments, such as resistance suits for resistance training in sports, conventionally comprise resistive bands secured to fabric. The resistive bands are positioned to resist expansion and contraction of muscles of the wearer as the body moves. The fabric typically comprises elastic resilient material so that the resistance garment also provides some compression in addition to resistance.
Conventional resistance garments have various disadvantages. They typically have seams and channels with bulky elastic bands that do not fit precisely or conform smoothly to the body, but instead tend to pucker up and chafe against the skin as the body portion moves. The seams and bulky elastic bands create unsightly and uncomfortable lines in conventional resistance garments that adversely affect their fit, fashion and function.
In this context, there is a need for resistance garments having improved fit, fashion and function.
According to the present invention, there is provided a garment, comprising a fabric configured to conform to a body portion of a wearer, wherein resistive zones are seamlessly integrally formed in the fabric, and wherein the resistive zones are positioned in the fabric to resist movement of the body portion of the wearer.
The fabric may be a knitted fabric or a woven fabric. For example, the fabric may be a three-dimensional (3D) knitted fabric.
The resistive zones may be resistive bands.
The fabric and the resistive zones may be formed using a circular knitting machine.
The resistive zones may be positioned in the fabric using virtual prototyping of a virtual model of the garment on a virtual model of the body portion. The virtual prototyping may comprise finite element analysis (FEA) of the virtual garment model on the virtual model of the body portion. The virtual model of the body portion may comprise a meshed, 3D model of the body portion.
The resistive zones may be seamlessly formed by varying knitting or weaving patterns of the fabric, varying composition of the fabric, or a combination thereof.
The garment may comprise an arm sleeve, a leg sleeve, a body sleeve, a pair of pants, a top, and combinations thereof. For example, the garment may comprise a resistance suit comprising the pair of pants and the top.
The pair of pants may comprise a waist and a pair of legs respectively terminating below leg calves of the wearer.
The resistive zones may be positioned in the fabric to extend downwardly from the waist to rearwardly encircle and anchor under and to muscles of the leg calves of the wearer. The resistive zones may forwardly encircle and anchor under and to the wearer's knee.
The body portion may comprise arms, legs, upper torso, lower torso, and combinations thereof. The resistive zones may be positioned to provide resistance to muscles of the wearer between the waist and the leg calves as the body portion moves. For example, the muscles may comprise gluteus maximus, upper leg muscles, lower leg muscles, and combinations thereof.
The resistive zones may be positioned to resist biomechanical movement of the body portion, limit range of motion of the body portion, or a combination thereof.
The fabric may comprise synthetic fibres, natural fibres, or a combination or blend thereof. For example, the seamless fabric may comprise polyamide and elastane.
The garment may be configured as a sportswear garment, an exercise garment, a running garment, a yoga garment, a rehabilitation garment, a cross fit garment, a veterinary garment, and combinations thereof. For example, the garment may be a rehabilitation garment, wherein the resistive zones are positioned to mimic targeted resistance provided by TheraBand therapy, sports taping, or a combination thereof.
The present invention also provides a method, comprising:
seamlessly and integrally forming resistive zones in fabric of a garment that is conformable to a body portion of a wearer, wherein the resistive zones are positioned in the fabric to resist movement of the body portion.
The resistive zones may be seamlessly integrally formed in the fabric by 3D knitting.
Embodiments of the invention will now be described by way of example only with reference to the accompanying drawings, in which:
The resistive zones 18 may comprise elongate resistive bands 18. Other equivalent or alternative shapes and geometries may also be used for the resistive zones 18. The resistive bands 18 may have reduced elasticity (ie, increased modulus of elasticity), reduced resilience or increased resistive force relative to the base fabric forming the major portions of the garment 10. For example, the resistive zones 18 may be about ten times stiffer than the base fabric.
The resistive bands 18 may be positioned in the fabric to resist movement of a body portion of the wearer. For example, the resistive bands 18 may resist or limit expansion and/or contraction of muscles in the body portion. This resistance to movement results in increased muscular work performed by the wearer when moving, and thereby increases efficiency of exercise or other physical activity. Further or alternatively, the resistive bands 18 may resist or limit biomechanical movement of the body portion, for example, resistance pants 10 may resist extension and/or flexion of the hip and/or knees. Further or alternatively, the resistive bands 18 may resist or limit a range of motion of the body portion. These embodiments may be useful for physiotherapy and rehabilitation, for example as an alternative or complementary treatment to TheraBand therapy and/or sports taping. For example, resistance pants 10 may comprise resistive zones 18 across the hip and waist regions that are configured to mimic placement of a TheraBand when performing exercises such as clamshell and sidestep exercises. The body portion may comprise arms, legs, upper torso, lower torso, and combinations thereof. Opposite ends of the resistive zones 18 may be anchored at spaced-apart anatomical anchor points on the body portion. The anatomical anchor points may comprise any and all suitable spaced-apart protuberances in bone, muscles and/or soft tissue of the body portion.
For example, the resistive bands 18 may be positioned in the fabric to extend downwardly from the waist 12 to rearwardly encircle and anchor under and to muscles of the leg calves 16 of the wearer. The resistive bands 18 may forwardly encircle and anchor under and to the wearers knee. The positioning of the resistive bands 18 on the front and rear sides of the garment 10 are illustrated in
In other embodiments, the garment 10 may be a sock, a stocking, an arm sleeve, a leg sleeve, a body sleeve, a pair of pants, a top, or a combination thereof. The sleeves, pants and tops may be full- or half-length depending on the desired use and appearance of the garment 10. The resistance garment 10 may be configured in any and all conventional shapes, sizes, cuts, patterns, lengths, widths, thicknesses etc. For example, the garment 10 may comprise a resistance suit comprising the pair of pants and the top. Referring to
The resistive force provided by the seamlessly-formed resistive zones 18 may be selectively varied and controlled based on the intended purpose of the resistance garment 10. For example, the position, 3D construction, thickness, width, surface area, material composition and fabric composition of the resistive zones 18 may be selectively and individually varied to provide different levels of resistive force suitable to the intended use and/or the intended user of the resistance garment 10. For example, the resistive force provided by the resistive zones 18 of a rehabilitation garment 10 may be lower than the resistive force provided by the resistive zones 18 in an exercise or cross fit garment 10. In further examples, the resistive zones 18 on a pair of rehabilitation pants for treating hip flexor strains may be arranged differently compared to the resistive zones on a rehabilitation pants for treating anterior cruciate ligament (ACL) strains in the knee. The resistive zones 18 may be configured to provide different levels of resistive force, such as easy, medium or hard levels of resistance. In some embodiments, the resistance provided by the seamlessly formed resistive zones 18 may be selectively varied throughout the resistance garment 10. For example, the resistive zones 18 for therapeutic compression socks may be configured so that resistance gradually decreases from the ankle towards the waist.
The resistance garment 10 may alternatively be implemented as a veterinary garment 10 for an animal, such as a horse or a dog. For example, the veterinary garment 10 may be configured as a training and/or rehabilitation garment for a race horse or a greyhound. The veterinary garment 10 may be configured to conform to the upper and/or lower leg of the animal, and the resistive zones 18 may be positioned and configured to resist movement of the animal's upper and/or lower leg.
The fabric may be a knitted fabric or a woven fabric. For example, the fabric may be a 3D knitted fabric. The fabric and the resistive bands 18 may be formed integrally with each other in a single process using a single machine, such as a flat knitting, warp knitting or circular knitting machine. The increased resistance of the resistive zones compared to the base material may be provided by varying knitting or weaving patterns of the fabric, varying composition of the fabric, or a combination thereof. Resistive zones 18 thus formed are seamlessly integrated into the base fabric. The fabric may comprise synthetic fibres, natural fibres, or a combination or blend thereof. For example, the fabric may comprise polyamide and elastane. Other equivalent or alternative fibres may also be used, for example, a nylon/lycra blend.
The resistive bands 18 may be planned and positioned in the fabric using virtual prototyping of a virtual model of the garment 10 on a virtual model of the body portion. The virtual prototyping may comprise FEA of the virtual garment model on the virtual model of the body portion. The virtual model of the body portion may comprise a meshed, 3D model of the body portion.
The invention will now be described in more detail, by way of illustration only, with respect to the following examples. The examples are intended to serve to illustrate this invention, and should not be construed as limiting the generality of the disclosure of the description throughout this specification.
Referring to
Four samples of the fabric and the resistive bands 18 were taken from the resistance sleeve 10 and subjected to tensile strength testing using a 30 kN Instron tensile tester with a 100 N load cell and a 40 mm gauge length. Each sample was preloaded with 0.5 N of force at a rate of 5 mm/s. Each sample was then extended to 80 mm more than the original gauge length at a rate of 5 mm/s. Upon reaching the 80 mm extension length the test was stopped and the jaws of the tester were returned to their starting positions and the sample removed.
The length and width of each sample was measured with a ruler taking the approximate average of three measurements. The thickness of the samples was measured using a digital fabric micrometre taking the average of three measurements. The modulus of elasticity of each sample was calculated by the Instron Blue Hill 3 program. The results of the tensile strength testing are set out below in Table 1.
The above results indicate that the seamlessly integrally formed resistive bands 18 had a greater modulus of elasticity relative to the base fabric forming the major portions of the garment 10.
A Biodex dynamometer was used to measure the effect of resistance pants 10 on leg movement. The movements tested were rotation about the hip joint, and rotation about the knee joint.
The results indicate that the resistance pants 10 with seamlessly integrated resistive zones 18 arranged in the “X” shaped configuration as shown in
Embodiments of the present invention provide resistance garments for humans and animals having integral seamless resistive zones that provide improved fit, fashion and function. The resistance garments with integral seamlessly formed resistive zones are precisely fitted to the body to produce a smoother, clean look. The resistance garments with integral seamlessly formed resistive zones conform smoothly to individual shapes of wearers and produce fewer visible lines. The lack of seams around the resistive zones provides for improved comfort as the body moves. The seamlessly integrated resistive zones are precisely positioned using virtual prototyping to optimise their functionality in resisting movement of one or more body portions of the wearer.
For the purpose of this specification, the word “comprising” means “including but not limited to,”, and the word “comprises” has a corresponding meaning.
The above embodiments have been described by way of example only and modifications are possible within the scope of the claims that follow.
Filing Document | Filing Date | Country | Kind |
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PCT/AU2016/050536 | 6/24/2016 | WO | 00 |
Number | Date | Country | |
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62184509 | Jun 2015 | US |