Patent Application
20230247731
This invention pertains to a glove that comprises a heating device that may be activated in cold weather. It is particularly suitable for use in gloves used by cyclists, motor cyclists as well as personnel who have to work in a cold environment.
U.S. Pat. No. 10,080,260 to Shin Bongchel discloses a fine heating wire having a small diameter that is applicable to various products. The fine heating wire is bendable, densely installed, and has high thermal efficiency. It includes a core formed with synthetic fiber material and a coil spirally wound around the outer portion of the core, The core connects one or more pairs of polyaramid fiber units. Each unit is formed by braiding dozens to hundreds of fine polyaramid fiber strands to maintain the diameter within 200-600 denier. The coil is formed of copper or copper alloy to withstand temperature rising up to 60° within five minutes when 3.7-12V power is supplied to maintain a resistance per unit length value equal to or greater than 0.5Ω/m. The diameter of the fine heating wire is minimized to be installed inside a slim fiber and is bendable and densely installed to be applied to products, such as gloves and socks.
PCT publication WO 9533358 A1 to Silzars et al teaches an improved heating fabric that can be used in a wide variety of applications, including garments, and, at the same time, permits washability of the final article in addition to excellent heating performance. Specifically, the instant invention provides a heating fabric of textile filaments having incorporated therein at least one conductive yarn comprising substantially non-conductive filaments having at least about 10 weight % metal plated thereon, the conductive yarn being integrated into the fabric in a continuous resistive circuit having at least two terminals, the terminals being connected to an electric power source having a voltage of less than about 30, the conductive yarn being incorporated into the fabric in a density sufficient to provide at least about 5 watts per square foot of fabric when the power source is applied.
This invention pertains to a glove for heating a hand 11 comprising an upper section 10 and a lower section 20 wherein:
A glove of this invention comprises an upper section 10 also known as a back part and a lower section 20 also known as a palm part.
In the context of this application, an inner surface of a layer is the surface closer (proximal) to the hand and an outer surface is the surface further away (distal) from the hand.
As shown in
In an alternative embodiment, the glove further comprises a water- impermeable membrane 16 located between the heating pad 14 and the first outer protective layer 12.
When a first fabric is present as part of the first outer protective layer 12 the first fabric may be a woven or knit fabric for example a fabric made from aliphatic polyamide yarn such as Cordura® from Invista®. Preferably, the first fabric has an areal weight of about 200 gsm. The first fabric may also be waterproofed.
When a first leather skin is present as part of the first outer protective layer 12, the leather may be natural or synthetic. In some glove designs the first outer protective layer 12 may comprise a section of first fabric and another section of first leather skin. In another design the first leather skin may be placed on top of the first fabric.
The membrane 16 is an optional feature that is waterproof but breathable. A suitable material is polytetrafluoroethylene (PTFE). Exemplary material combined with a cross-linked polyurethane coating is available from PIL Membranes Ltd, King's Lynn, England under the tradename Porelle®. Another suitable material is expanded polytetrafluoroethylene such as Gore-Tex from W. L. Gore, Newark, Del. An alternative membrane can be a TPU membrane.
The fabric of heating pad 14 may be a non-woven, woven or knit fabric in which the yarns are staple fibers. An exemplary fabric style is a 2×2 twill. Typically the fabric has an areal weight of from 60 to 300 gsm. The heating pad 14 has an inner face 14a and an outer face 14b. Preferably the fabric comprises at least 30 weight % of oxidized polyacrylonitrile yarns and at least 30 weight % of p-aramid yarns, more preferably in the form of an intimate blend. Intimate blending is a technique of mixing two or more dissimilar fibers into a very uniform mixture and is well known in the textile arts. Oxidized polyacrylonitrile (OPAN) fiber is manufactured from a polyacrylonitrile precursor fiber (PAN). The PAN precursor fiber is solution spun and processed through a high temperature air oven to stabilize its molecular structure. An exemplary OPAN fiber is available from SGL Carbon under the tradename Panox. An exemplary p-aramid fiber is Kevlar® merge 1K292 from DuPont de Nemours Inc., Wilmington, Del. The OPAN fiber provides heat dissipation properties while the p-aramid fiber contributes to impact and abrasion resistance.
At least one conductive wire extends from the electronic module 30 over at least part of the inner surface 14a or outer surface 14b of the heating pad 14, the conductive wire being held in place on the inner surface 14a or outer surface 14b of the heating pad 14 by a fixing means. The fixing means may be a stitching yarn forming an embroidery pattern or an adhesive. The adhesive may have a nonwoven backing or scrim fabric to provide additional support. In some embodiments both an adhesive and stitching yarn may be used. When the fixing means is a stitching yarn, the embroidery pattern formed by the stitching yarn is preferably a chain stitch, a buttonhole stitch, a blanket stitch, a running stitch, a satin stitch or a cross stitch.
In one embodiment, at least one conductive wire extends from the electronic module 30 over at least part of at least one finger and over at least part of the back hand area of the inner surface 14a or outer surface 14b of the heating pad 14. In another embodiment, two conductive wires extend from the electronic module 30 over all the fingers and part of the back hand area of the inner surface 14a or outer surface 14b of the heating pad 14.
Preferably the second fabric of the upper section is a knit fabric comprising cotton or polyester yarn. An intimate blend of cotton and polyester yarns may also be used.
Any suitable temperature measuring device 13 may be used. Examples include a positive temperature coefficient (PTC) resistor, a negative temperature coefficient (NTC) resistor, a K thermocouple sensor or a platinum temperature sensor. In a preferred embodiment, the temperature detecting sensor 13 is a resistance temperature detector (PT1000).
The electronic module component 30 comprises an accelerometer 33 that activates or deactivates the battery power source as a result of hand movement of the glove, and a digital processor 35 wherein the processor receives live temperature data input received from the temperature detecting sensor 13 and predicts via an algorithm whether to provide heat to heating pad 14 or maintain heat or turn off heat. The temperature detecting sensor 13 is connected to a temperature sensor driver 39.
Other elements of the module are a battery power gauge 38, a charging bay connector 42 and an external on/off switch 44. Preferably this external switch is located on the glove. Connector 42 which is located in a pocket on the inner surface 18 of the outer protective layer 12 allows removal of the battery 32 for charging.
Any suitable battery may be used with a lithium battery or a ceramic lithium battery being representative examples.
As shown in
In some embodiments, a fabric liner 22 is located next to the innermost (proximal) surface of the second outer protective layer 17. This liner provides protection against heat and abrasion. A knit is a preferred fabric style for fabric liner 22 because of its flexibility in the palm area. The fibers of the fabric liner 22 may comprise aromatic polyamid, aliphatic polyamid, polyethylene, polyethylene terephthalate, cotton, wool or blends thereof.
The glove construction is in compliance with the following performance standards:
EN 13594:2015 (Protective Gloves for Motorcycle Riders—Requirements and Test Methods).
EN 388:2016 (Protective Gloves Against Mechanical Risks).
EN 511:2006 (Protective Gloves Against Cold)
A 2×2 twill woven fabric heating pad 14 having an areal weight of 250 gsm was made from an intimate blend of 50 weight percent of p-aramid Kevlar® K29 and 50 weight percent of pre-oxidized acrylonitrile spun yarns. The Kevlar® fiber was from Dupont and the pre-oxidized acrylonitrile fiber was Panox® grade T320-1.7/1.39-A110 from Filtes International, Capriolo, Italy.
The fabric heating pad 14 was cut into the shape of a hand. Two non-insulated stainless steel 316L heating wires each having a linear density of 1.12 g/m and a resistivity of 6 ohm/m were arranged in parallel on one side of the fabric pad 14 and held in place by a finger shaped quilting pattern using polyester yarn. The two wires covered the finger portion of the hand and never crossed each other. The total impendence of the wiring was 5.1 ohms.
This fabric heating pad 14 was prepared in a similar way to Example 1 except that the fabric was a needle punched white polyester nonwoven fabric having an areal weight of 60 gsm and only one stainless steel 316L heating wire was incorporated into the pad. The heating wire had a linear density of 2.3 g/m and a resistivity of 2.4 ohm/m. The total impendence of the wiring was 5.1 ohm.
A battery of 7.4V with a maximum current of 1.45 A was connected to the heating pad wires delivering an energy of 10W. An infrared camera monitored the temperature rise on the surface of the fabric heating pad 14. After 60 seconds the temperature rise of Example 1 was 33° C. while that for the Comparative Example was only 27.6° C. demonstrating the advantage in warming effect provided by the construction of Example 1. Further, the heat coverage area of the fingers of Example 1 was significantly better thus providing better comfort and lower energy consumption for the same heat feeling.
