Patent Application
20110155417
The present invention relates to a conducting wire structure and a method of manufacturing a conducting wire core and particularly to a conducting wire containing a special conductor structure.
Ever since human being started using electric power, how to transmit the electric power is a subject constantly pursued by mankind. In the early development stage of electrical science, Ohm's law was discovered. Ohm's law can be summed up in an equation: V=IxR, where V represents voltage, R represents resistance, and I represents current passing through the resistance R when the voltage V is applied thereon. Theoretically, whether electric power can pass through an object depends on the resistance of the object. According to Ohm's law, current I flows through a path of the lowest resistance. Hence applying a voltage on an object, current tends to flow through the portion where the resistance is the lowest. In order to reduce electricity loss during transmission, aside from selecting a conductor with a smaller resistance, other phenomena of electric power transmission on the conductor also have to be taken into account. One of such phenomena is “skin effect”. It is not intended here to discuss the mathematic formula of the “skin effect”. In short, “skin effect” is a physical phenomenon in which resistance of a conductor increases with increasing of AC frequency. More specifically, as AC frequency increases, the resistance of a conductor also increases such that current tends to flow on the outer circumference or surface of a conductor (referring to
Concerning the “skin effect”, the conductor of the conducting wire ought to have its shape or arrangement changed in a desired manner to allow maximum current to pass through and reduce loss and improve utilization of resources. One of practices is to maximize the surface area of the conductor and shrink the cross section thereof where current does not flow through. More specifically, a conventional approach is changing a single conductor to a plurality of conductors bundled together to become a stranded wire. Then the surface area of one conductor can be enlarged to the surface area of multiple conductors. For instance, R.O.C. patent No. M319508 entitled “Improved cable structure” includes two or more conductors wound to form a conducting wire. Such a structure can increase the surface area of the conductor allowing high frequency current to pass through and also shrink the cross section at the center of the conductor. Its manufacturing method is relatively simple, and the stranded wire can be used on most duty voltage or frequency of conducting wire, thus is widely adopted. Various alterations have been developed based on the aforesaid technique of the stranded wire. For instance, R.O.C. patent No. M339783 entitled “Improved wire structure for concentrator photovoltaic modules” discloses another type of single-core or multi-core conducting wire in which one or more core is bundled together to once encase a white Teflon wire. Another R.O.C. patent No. M347650 entitled “XLPE hyper voltage power cable structure for 400 KV” is applicable for high voltage power cable. It is formed by bundling a great deal of copper cores. Other references also are available in R.O.C. patent pub. Nos. 394289 entitled “Improved conducting wire structure”, 405746 entitled “Differential pair cable”, and M340532 entitled “Energy saving electric cord and cable”.
Most of the conventional techniques set forth above adopt stranded wire to increase current flowing amount. There is another approach by trying to increase the surface area of a single conductor, such as R.O.C. patent No. I270087 entitled “Core of electric power or signal transmission wire”. It discloses a wire containing a core. The core has an equilateral geometric section adjacent to a scalene geometric section. The scalene geometric section has an extended section directed inwards to form a surface area greater than the equilateral geometric section, thus can be used for power or signal transmission. While it provides a breakthrough over the conventional technique of round conductor wire and offers enhanced electric conduction capability, fabricating the scalene geometric section involves more complex processes than manufacturing the round conductor. Moreover, different types of scalene geometric section have varying physical strengths and their capability to withstand external forces such as compression or bending also are different, and might even be inferior to the round conductor. Taking into account of fabrication cost, speed and physical strength of the conductor body, its application is limited.
Although the stranded wire provides a wider application scope, it still leaves a lot to be desired, especially at present when almost countries around the world pursue “Green power” or “Green energy”, and various energy-saving regulations are being proposed or established, to improve transmission efficiency of high power conducting wire to avoid energy loss on power conducting wire of electric appliances. However, changing the form of the conducting wire incurs additional manufacturing difficulties and higher cost. All these show that there are still rooms for improvement.
In view of the aforesaid problems occurred to the conventional conducting wire, the primary object of the present invention is to provide a conducting wire structure and method of manufacturing an inner core of the conducting wire that offers the core can enlarge surface area of a conductor to facilitate high frequency current passing thereby to enlarge current flowing path and increase current conducting amount.
The conducting wire structure according to the present invention includes at least one core and an insulation skin encasing outer edge of the core to form a conducting wire. The core contains a plurality of flattened conductors formed in a flattened cross section and stacked together. The flattened conductors are interposed by an insulation layer which bonds two neighboring flattened conductors, and then the bonded conductors are stacked to form the core in an integrated manner. The flattened conductors in the core can conduct an identical electric signal, hence the combined surface area of the flattened conductors can also transmit electric power or signals to maximize the conductive area of a single core. The present invention also provides a method to fabricate the core. The method includes procedures as follow: providing a plurality of flattened conductors with flattened cross sections through a flattened conductor fabrication means; coating an insulation layer on the surfaces of the flattened conductors through a coating means; stacking the flattened conductors coaxially to form a core. The flattened conductor fabrication means can form the flattened conductors from calendering conductors with any shapes or cutting a flattened conductor. By means of the present invention, the flattened conductors can be stacked to get maximum conductive surface area and fabricated at a lower cost and faster speed to produce a conducting wire of a higher electric conductivity.
The foregoing, as well as additional objects, features and advantages of the invention will be more readily apparent from the following detailed description, which proceeds with reference to the accompanying drawings.
The present invention aims to provide a conducting wire structure and a method of manufacturing a core in the conducting wire. Referring to
In order to facilitate production and promote wider applications of the conducting wire 10 provided by the present invention previously discussed, the present invention also provides a method to fabricate the core 2 formed by stacking a plurality of flattened conductors 21. Referring to
While the preferred embodiments of the invention have been set forth for the purpose of disclosure, they are not the limitation of the invention. For instance, there is no limitation on the thickness of the flattened conductors 21 and insulation layer 22. The insulation layer 22 can be formed by selecting varying insulation materials of different insulation strengths according to different requirements, thus modifications of the disclosed embodiments of the invention as well as other embodiments thereof may occur to those skilled in the art. Accordingly, the appended claims are intended to cover all embodiments which do not depart from the spirit and scope of the invention.
