This application claims priority from Application PCT/GB2015/052553, filed Sep. 4, 2015, which is deemed incorporated by reference in its entirety in this application.
Not applicable.
This invention relates to yarns incorporating electronic devices and their manufacture. It relates particularly to such yarns in which the devices and electrical connections thereto are protected. Also part of the invention is a method of manufacturing the yarns for incorporation into fabric products for example, although other uses are contemplated.
International Patent Publication No. WO2006/123133, the contents whereof are hereby incorporated by reference, discloses a multi-filament yarn including an operative devices confined between the yarn filaments, and a method for its manufacture. The yarn filaments are typically polyester or polyamide. One or more of the yarn filaments can be electrically conductive and coupled to the device to form an electrical connection thereto. These filaments can be metal filament wires in the form of a polymeric monofilament yarn with either a copper or silver metal core wire. The device may take one of various forms, such as a silicon chip, a ferro-magnetic polymeric chip or a phase change chip.
Reference is also directed to Japanese Patent specification No. 2013189718A and US Patent publication No. 2013/092742, the disclosures whereof are hereby incorporated. Both describe yarns carrying electronic devices within a protective outer layer or sheath.
Yarns of the above International Publication are effective and can be used in fabric products. However, where the device has an electrical connection the connection will be exposed on the yarn surface and thereby compromised by contact with other yarns or elements, or by external conditions. The Japanese and US references go some way towards addressing this issue, but do not provide a resolution.
A primary aim of the present invention is to avoid risk of such exposure and thereby enhance the efficiency of a device in a series of devices installed in a yarn. Another aim is to incorporate devices and connections thereto in a yarn in such a manner that they are unobtrusive. According to the invention an electronically functional yarn comprises a plurality of carrier fibres forming a core; a series of electronic devices mounted on the core with conductive interconnects extending along the core; a plurality of packing fibres around the core, the devices and the interconnects; and a retaining sleeve around the packing fibres, wherein the core, the devices and the interconnects are confined within the plurality of packing fibres retained in the sleeve. The interconnects can comprise at least one conductor that extends the length of the yarn. By mounting the devices and interconnects on carrier fibres they are more easily retained in the body of the yarn and within the packing fibres. The packing fibres can be untwisted; i.e. extend generally parallel to the yarn axis, but may be selectively bunched or twisted to fill spaces between the devices. A separate filler material may also be used for this purpose. These options can serve to preserve a substantially uniform cross-section along the length of the yarn and between the devices. The packing fibres, and a filler material if used, may be selected to either encourage or discourage the absorption of moisture by the composite yarn. In preferred embodiments the carrier fibres include at least some which are arranged in a planar array and the electronic devices may all be mounted on one side of the array. The devices can then be easily mounted on at least two of the carrier fibres, but mounting on one can be sufficient in many applications. This means that different devices can be mounted on different ones or groups of the carrier fibres.
The electronic devices incorporated in yarns of the invention can take many forms, including operative devices such as a silicon chip signaling devices such as light, sound or symbol generators, micro-controllers and energy harvesting devices. Particularly suitable for use in yarns of the present invention are ultra thin electronic dice.
The packing fibres in yarns of the invention can be independent from one another; i.e. relatively movable, but at least some may be bonded to secure the integrity of the yarn, particularly around a device. Such a bond can be an adhesive bond, or established by heating the relevant zone. Some independence is preferred to allow the fibres relative movement when the yarn is bent or twisted. This assists in maintaining a high degree of uniformity in the overall yarn diameter. The packing fibres can be natural fibres, man-made fibres or synthetic fibres such as polyester or polyamide, and typically have diameters in the range 10-15 μm.
The carrier fibres for the devices can be of the same material as the packing fibres, but the material will normally have a high melting point, typically above 350° C., and have a high level of thermal and chemical stability. The reason for this is to ensure they can withstand the heat generated when interconnects are coupled to the electronic devices. Semiconductor chips with solder pads for the interconnects are normally first mounted on the carrier fibres and the interconnects, for example fine copper wire, can be coupled to the pads by using a reflow soldering technique. This technique involves depositing a small quantity of solder paste on the solder pads and then applying heat to melt the paste and then create a strong metallic bond. The carrier fibres forming the yarn core must hold the devices as this process is completed, and will normally have diameters in the range 10-100 μm. Polybenzimidazole or aramid based fibres such as PBI, Vectran or Normex are examples of some which can be used as carrier fibres. Typically the core will consist of or include four carrier fibres will extend side by side providing a platform for the devices to which they are attached, although the devices will not necessarily be attached to or mounted on all the fibres forming the platform. The devices themselves are normally enclosed in a polymeric micro-pod which also encloses the adjacent length of carrier fibres to establish the attachment, normally with the solder pads on the device and the interconnects. The devices and the carrier fibres can also be hermetically sealed between two ultra thin polymeric films. The interconnects, typically fine copper wire of around 150 μm diameter, normally extend on and/or between the carrier fibres.
The retaining sleeve can take many different forms, and may vary depending upon the form taken by the packing fibres and to some extent, the intended use of the yarn. It will normally be a fibre structure comprising one or more of natural, man-made and synthetic fibres. Typical sleeves are interlaced fibre structures, but interlooped knitted fibre structures can also be used. Its function is to preserve the arrangement of the packing fibres around the devices, carrier fibres and interconnects. It can take the form of a separate yarn helically wound around the packing fibres, a woven or knitted fabric structure, or a woven or knitted braid. A fibre or yarn structure is though preferred to most easily accommodate bends and twists.
The invention is also directed at a method of manufacturing a yarn incorporating electronic devices. The method comprises mounting electronic devices with interconnects coupled thereto in sequence on a core consisting of a plurality of carrier fibres; feeding the carrier fibres with the mounted devices and interconnects centrally through a channel with packing fibres around the sides thereof to form a fibre assembly around the core; feeding the fibre assembly into a sleeve forming unit in which a sleeve is formed around the assembly to form a composite yarn; and withdrawing the composite yarn from the sleeve forming unit. The channel through which the core with the mounted devices is fed can be formed centrally in a carrousel having separate openings around its periphery through which sleeve fibres are fed for forming the sleeve. This arrangement is particularly suitable when the sleeve is to be braided as braiding fibres can be fed through the carrousel directly into a braiding unit forming the sleeve around the packing fibre assembly. However, as described below, the sleeve fibres can be warp or weft fibres feeding into a circular warp or weft knitting head. The yarn may be withdrawn from the sleeve forming unit with the packing fibre assembly being effectively drawn in a pultrusion process at a rate determined by the speed at which the sleeve forming unit operates. If any filler material is to be used this may be added at the entrance to the channel. Any bunching or twisting to fill the spaces between the devices with packing fibres can be effected between the channel and the sleeve forming unit.
The invention will now be described by way of example and with reference to the accompanying schematic drawings wherein:
In the yarn shown in
A sleeve 12 surrounds the packing fibres 10 to stabilize the fibre assembly with the pods 4 and interconnects 8 held centrally therein, and particularly to provide additional protection of the interconnects from exposure and mechanical stress during use. Thus, fabrics including yarns according to the invention can survive washing and tumble drying for example, in addition to normal wear and tear during use, with less risk of compromise to the interconnects and the functionality of the chips or other devices installed in the yarn. The sleeve shown comprises a separate textile yarn 14 helically wound around the packing fibres 10. Alternative forms of sleeve are woven or knitted braids. A wide variety of fibres can be used for the sleeve, as noted above, which is normally a textile structure with fibres of diameter in the range 10-50 μm.
A process for manufacturing a yarn of the invention is illustrated in
The assembly comprising the carrier (6) and packing (10) fibres passes from the channel 18 to a sleeve unit 24. In the process shown in
The manufacturing process shown in
The central duct 66 has a shaped conical opening for receiving the packing fibres, to ensure they are arranged around the core 34 and its micropods and interconnects. The duct 66 extends the full length of the yarn guide tube 68 and rotatable cylindrical yarn guide 70 to retain the packing fibres within the sleeve fibres as they are positioned to be knitted into the sleeve in the needle cylinder 72. Thus, in the completed yarn, the packing fibres within the sleeve surround and enclose the carrier fibres, micropods and interconnects ensuring that the interconnects extend along the core. The process illustrated would use a warp knitting process in which the cylindrical yarn guide 70 oscillates to properly orient the sleeve fibres prior to knitting. The process can be adapted for weft knitting, but the orientation of the fibres around the duct 64 prior to knitting is more complex.
Number | Date | Country | Kind |
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1415837.2 | Sep 2014 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2015/052553 | 9/4/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/038342 | 3/17/2016 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5318845 | Tanaka | Jun 1994 | A |
6437422 | Solomon | Aug 2002 | B1 |
7592276 | Hill | Sep 2009 | B2 |
8155497 | Shtein | Apr 2012 | B2 |
8860012 | Park | Oct 2014 | B2 |
20090139198 | Dias | Jun 2009 | A1 |
20100325770 | Chung | Dec 2010 | A1 |
20130092742 | Brun et al. | Apr 2013 | A1 |
Number | Date | Country |
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2472026 | Jan 2011 | GB |
2001064870 | Mar 2001 | JP |
201389718 | Sep 2013 | JP |
WO 02084617 | Oct 2002 | WO |
WO 2008080245 | Jul 2008 | WO |
Entry |
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Search Report issued by the UKIPO in respect of UK Patent Application No. 1415837.2 from which this application claims priority dated Jan. 21, 2015. |
The International Search Report issued during the International phase of the PCT application, dated Jun. 22, 2017. |
Number | Date | Country | |
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20170275789 A1 | Sep 2017 | US |