The present invention relates to mobile phone pouches and containers for holding said phone for their owners during recreation and exercising activities.
Plastic phone cases have been around for almost as long as mobile phones have been commercially available. While protective of the phone, these cases are made for impact resistance and are often wrapped around their phones for the service life of the case. Owners will often secure their phone in its protective case in a pocket or purse when not in use, and will use wired or blue-tooth headphones or earbuds to make calls or listen to music, while the phone is so secured. Wired ear phones present the issue of entanglement with one's clothing, hair style or interference with one's activity, and are becoming scarce with the advent and popularity of wireless Bluetooth earbuds. Many mobile phone today don't even come with a 3.5 mm jack for receiving the pin shaped plug of wired headphones. Earbuds don't present wire entanglement issues, but they must be paired with their mobile phone device and they must be recharged for optimal performance.
There are also devices for securing mobile phones to the arms of runners. Such devices usually have a pocket and a Velcro strap for affixing the phone to the wearer. They are typically paired with earbuds for listening to music. Other devices are designed to allow bikers to attach their phones to the frame or handle bars of their bike. Such devices are generally bulking and require or at least encourage the use of wired or wireless ear phones.
While there have been plenty of innovations in phone securing devices, there still appears to be a need for a simple mobile phone pocket that does not inconvenience the wearer during recreational and exercising activities.
In a first embodiment of the invention, a soft mobile phone pouch is provided, which comprises an elastic fabric, forming a soft-walled pocket having a longitudinal length, a width and a depth, an opening for receiving a mobile phone, so that said mobile phone is substantially disposed within said pocket, and one or a plurality of fasteners for removably attaching said pouch to an article of clothing, whereby the internal speakers of said mobile phone are positioned to direct audio sound to the ears of the wearer.
In a further embodiment the soft mobile phone pouch is affixed by pin fasteners to the rear of a cap or hat, so that the phone's internal speakers deliver a first sound channel to the right ear and a second sound channel to the left ear of the wearer. Similarly the pouch can be affixed to the front or back of a shirt or jacket, to also direct (on an upward trajectory) a first sound channel to the right ear and a second sound channel to the left ear of the wearer.
In a further embodiment, the soft phone pouch includes an elastic material for gripping a plurality of corners of the phone or phone case. Preferably, the pouch is smaller than the mobile phone and stretched to accommodate the phone, when the phone is inserted therein. In other embodiments, the elastic fabric is stretched to expand substantially around the periphery of the mobile phone and is then snapped in place. In still other embodiments, the pouch is provided with a circular or an oval opening on at least one side for receiving said phone. The opening may be a folded fabric seam and may also comprise elastic fabric. In most preferred embodiments, the elastic fabric is a blend comprising two or more of: cotton, polyester, Spandex (Lycra or elastane) and nylon fibers. In other embodiments the elastic fabric is a stretchy cotton or synthetic fiber blend. Preferably the fabric can stretch at least about 10% and more preferably at least about 50%. In other embodiments, the elastic fabric is substantially sound transparent, or substantially allows sound to pass through with minimum interference. One or more removable fasteners, such as button pins, can be used to affix the pouch to a cap or shirt, for example. An electromagnetic cage material, such as metal threads of copper, aluminum or steel, can also be added to the fabric of the pouch for reducing the transmission of electromagnetic waves from the phone to the user. Preferably this cage material is made to flex and bend to allow the pouch to reversibly stretch to receive the phone. The pouch can also be made waterproof by using closed systems including waterproof or water resistant materials and closure systems.
The following drawings illustrate preferred embodiments of the invention as well as other information pertinent to the disclosure, whereas:
With reference to the Figures, and particularly to
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The pouch can also be made waterproof by using closed cell foam (neoprene), waterproof zippers, zip lock fasteners, and/or liquid water impermeable layers that preferably allow sound waves to pass (air breathable), such as TPU film, GoreTex (stretched PTFE film), or non-waterproof fabrics treated with fluorocarbon compositions (SCOTCHGARD water shield) to make them water resistant.
Stretch fabrics are either 2-way stretch or 4-way stretch. 2-way stretch fabrics stretch in one direction, usually from selvedge to selvedge (but can be in other directions depending on the knit). 4-way stretch fabrics, such as spandex, stretches in both directions, crosswise and lengthwise. Stretchy materials refers to fabrics which can stretch without breaking the fibers and return to its original length. This stretch of the fibers provides the preferred tapes and wraps of this invention made with them the much needed ease, drape, comfort and fitting. See https://sewguide.com/stretchy-fabric/, which is incorporated herein by reference.
Knits:
Most of the knit fabrics have some stretch. Usually, it is a 2-way stretch, with less stretch in the weft direction. The stretch of a knit fabric makes it one of the most suitable fabric for tape and wraps. Jersey is a light to medium weight knit fabric with good stretch. Other suitable knit fabrics are: 3×3 Rib Knit, Bamboo Jersey, Doubleknit Rayon Blend, Interlock twist jersey, Double knit, Sweater Knit, Silk Mesh Knits and Silk Jersey.
Spandex:
Also suitable for this invention are Spandex fabrics, which is a generic name for stretchy fabrics with elastic content—the base could be cotton, nylon or wool and Lycra, a spandex fabric which is trademarked by Dupont Company. Its ability to stretch to almost 300-400 percentage on its own. The stretchiness of Spandex depends on its elastane content; 1-5% is desirable, whereas for sportswear an elastane content of about 12-15% is more preferred Spandex blends.
Spandex Blends:
When blended with other fibers spandex can lend about 2-20% of its elasticity to the new fibers.
The elastic fabrics of this invention used to make the pouch 100 should be substantially “acoustically permeable”, capable of permitting sound to penetrate through the fabric. Sound travels through the air, so the fabric should be breathable to air, if sound is to make it through the fabric. If one can breathe through or blow through the fabric, it is probably acoustically permeable enough for this invention. Elastic fabrics can be chosen that have an open weave or knit and are breathable. Natural fibers such as cotton, linen, bamboo, and wool, alone or blended with spandex, rubber, or synthetic rubber, or fabrics made from rayon, nylon, polyester and or acrylic. The elastic fabric useful for this invention should have stretch memory (can be returned to their roughly their original tensity when stretched over a large phone or exposed to humidity). Lucia and Cara fabrics from Camira, commonly used for office seating, or cotton, cotton and polyester, bamboo, polyester and spandex or their blends commonly used for socks, would also be desirable. Cotton and polyester blended fiber sock fabrics are durable, water-resistant, and soft (so they won't scratch the phone screen). Bamboo fabric is also a good choice, since it breathable, stretchable, elastic, soft, lightweight, and hypoallergenic and antimicrobial.
The pouches 100 of this invention are preferably removably or permanently fastened to an article of clothing, such as a hat, blouse, shirt or jacket. Adhesive, rivets, stud buttons, or sewn threads could be used to fix the pouch to clothing, but it may be more desirable to use releasable fasteners, safety pins, threaded rivets, or button pins, which allow for separation of the pouch from clothing for cleaning and the like. One useful option are jean button pins, often used for jeans waist tightening. They come as sets of button pin cap 210 and rivet pin 211, shown in
The pouches of this invention can also contain an EMF or RF shielding material, often referred to as Faraday fabric. Electromagnetic and radio frequency radiation cannot pass through holes in conductive material which are smaller than their wavelength. In this fashion, it is possible to shield a wearer's head, body and particularly the brain from EMF or RF radiation from the mobile device in the pouch 100 with a conductive metal or graphite wire-mesh, impregnated yarn or weave, or sputtered type coating. When encountering this electromagnetic shield, radiation from the mobile phone 50 induces a displacement of electrons inside the conductive material, which causes, in return, the radiation to be reflected back inside the pouch 100 instead of into the head and brain of the wearer. While such protection will interfere with calls and internet access, it should not interfere with music previously saved in local storage on the mobile phone. It should be substantially acoustically transparent, or breathable, for this purpose.
A metallic layer, such as a silver or copper layer, on the pouch or woven with or coated onto the threads of the fabric, acts as a wire-mesh and shields what's outside the pouch from RF/EMF. The material used for copper compression socks may be useful as a RF/EMF block. Copper compression socks use infused copper, such as Cupron Antifungal fibers, or copper-based conductive yarn, which is woven in the fabric. Winter touch screen gloves also use this property to allow users to operate touch screens on their phones without taking off their gloves.
Other fabric choices could also include more specifically designed Faraday cages, mesh, fibers or fabric, EMF/EMI/RF fabric, etc. These shielding materials work because radiation in radio frequencies (RF) is blocked by graphite, graphene, and certain metals, such as: gold, silver, copper, aluminum, steel, stainless steel, but because of its RF wavelength, the metal doesn't even have to be solid—it can be a solid cage or flexible mesh, screen, film or woven or knitted fibers, or natural or synthetic fibers coated with metals, such as by sputtering. Many scientific facilities are lined with materials like this to prevent outside radiation from interfering with sensitive measurements. Available shielding fabrics are constructed of meshed nettings of multiple blended fibers with random mesh opening sizes. This design eliminates frequency-specific open slots, preventing peaks of EMI/RF leakage and results in an exceptionally flat shielding effectiveness profile across its specified frequency range. It also ensures a tight EMI/RF seal at seams, connections and terminations.
Another specific material useful for this purpose is called Amradield High Conductive Silver Fiber Fabric, available from Amradield Professional Textiles Factory, 1158 Laodong Rd., Suzhou, 215004, CN. Amradield fabric is a highly electrically conductive silver/nylon material which is very soft, stretchable and flexible. https://www.amazon.com/Grounding-Conductive-Electrode-Magnetic-Blocking/dp/B07V3VTBWV. Amradield fabric contains radiation EMF protective, silver conductive fibers that provide a shielding cage. This shielding electromagnetic fabric product is claimed to possess a surface resistance: below 0.1 ohm, average attenuation of 70 dB from 10 MHz-3 GHz, RF/EMI/EMF/LF blocking, super earthing/grounding, anti-static/radiation/radio wave/microwave properties. This technology is potentially capable of blocking up to 99% of microwaves, which includes wifi radiation, bluetooth, and cellphone radiation. It contains elastic nylon tri-cot fabric with vacuum sputtered silver coated thereon. The silver/nylon fibers/fabric is very soft and flexible. It is described as a stretchable fabric.
Another stretchable material suitable for the pouch fabric is LVFEIER anti jamming shielding electromagnetic wave radiation shielding cloth, available from Lvfeier Maternity, Shiyan DHKQ Manufacture and Trading Co., Ltd., 207, +, , , 442012, CN. This elastic material elastic, can be worn close to the body, and used for headscarves, underwear, hats, etc. High shielding (non-intermediate shielding) materials are used to shield radio frequency signals, such as 3G, 4G, 5G, WiFi, mobile phones, GPS, Bluetooth. Used for EMP protection, mobile phone signal shielding, EMI radiation reduction, radio meter shielding, effective shielding of microwave signals, telephones, intelligent instruments, security systems, radar, military broadcasting, etc. It can be used for making radiation-proof clothes, radiation-proof underwear, radiation-proof caps, radiation-proof shorts, radiation-proof headscarves, radiation-proof pajamas, radiation-proof bedsheets, radiation-proof pillowcases, radiation-proof sleeping bags, etc. Raw fiber materials include 80% high elasticity spandex, 20% silver.
Another such material, SM-10 RF Green® shielding fabrics are offered in nickel and copper plated polyester mesh netting to provide outstanding shielding effectiveness and surface conductivity. These fibers and/or fabrics accommodate complex contours and shapes, and could be used in the pouch.
Recently, companies like Silent Pocket have integrated meshes into bags and cases that totally isolate devices from incoming signals. Researchers at Drexel University have managed to create a Faraday fabric by infusing ordinary cotton with a compound called MXene.
RF radiation is not known to be harmful in the doses and frequencies we normally get exposed to in everyday life. The FCC makes sure no device exceeds certain thresholds. But there's also the possibility that one's phone or laptop is naively connecting to public Wi-Fi, getting its MAC number skimmed by other devices, and otherwise interacting with the environment in a way you might not like. And with the amount of devices emitting radiation right now, who wouldn't mind lowering their dose of RF radiation just a little.
From the foregoing, it can be realized that this invention provides improved mobile phone pouches for securely fastening mobile phones to clothing such as hats and shirts. The pouches of a first embodiment, provide for some acoustic transparency so that wearers can hear audio from their phone's internal speakers, preferably in stereo. Although various embodiments have been illustrated, this is for the purpose of describing, but not limiting the invention. Various modifications which will become apparent to one skilled in the art, are within the scope of this invention described in the attached claims.
The present application is a continuation-in-part application of U.S. Ser. No. 16/663,540, filed Oct. 25, 2019, which is hereby incorporated by reference it is entirety.
Number | Date | Country | |
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Parent | 16663540 | Oct 2019 | US |
Child | 17394731 | US |