In the short video here, we’ll walk you through the initial steps in working with NEWT on your custom cable design and will introduce you to your NEWT team members who will be communicating and collaborating with you on your project. Take a look!
Advancing innovation in wire for over 100 years
In the short video here, we’ll walk you through the initial steps in working with NEWT on your custom cable design and will introduce you to your NEWT team members who will be communicating and collaborating with you on your project. Take a look!
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Achieve 2X or even 3X improvement in Q factor using our proprietary TRUE Litz designs and constructions
Leading industry manufacturers have achieved their highest Q factor when using our TRUE-Q™ Litz wire
Ideal for use in Wireless Power Transfer Applications ~ 90KHz
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With much of the electronics industry focused on designing for high efficiency and form factors that grow ever smaller, engineers increasingly design magnetic coils and windings to operate at high frequencies into the megahertz range. Higher frequencies create stronger magnetic fields and tighter coupling with less copper that fits into smaller physical spaces. This move to higher frequencies usually requires new chipsets, magnetic cores and other components suited for those frequencies. As a result, new winding topologies have come into the market. In particular, preformed Litz wire has become a preferred choice for HF magnetics due to its unique topology and construction. This article explains what Litz wire is, how it’s constructed, how it helps produce magnetic devices that are smaller, cooler and more efficient, and how the unique benefits of preformed Litz help engineers achieve the goals that modern electronics must meet.
To begin, Litz wire offers three substantial benefits in the design of such HF magnetic devices. First, magnetic devices using wound copper Litz wire operate more efficiently than those using traditional magnet wire. For example, in the low kilohertz range, efficiency gains compared to ordinary wire can exceed 50 percent, while in low megahertz frequencies, 100 percent or more. Second, by preforming Litz wire, the fill factor, sometimes called packing density, is dramatically improved. Litz wire is most often formed into square, rectangular and keystone shapes, enabling design engineers to maximize the Q of circuits and minimize losses and AC resistance of the device. Third, as a result of that preforming, devices using preformed Litz wire fit more copper into smaller physical dimensions than those using ordinary magnet wire.
These characteristics have established Litz as the preferred choice of design engineers across a wide array of products and devices for many years. Yet, accelerating growth in the electronics industry has popularized Litz wire, and preformed Litz in particular, even further.
Innovation in artificial intelligence and robotics, autonomous vehicles for commercial, military and private use, advances in medical technology, computing and telecom, along with dozens of other marketplace segments have spawned a worldwide, accelerating demand for technology products.
Including the consumer, industrial and military market segments, electronics collectively accounts for a significant and growing portion of the nation’s—and even the world’s—gross domestic product. For instance, according to Consumer Technology Association (CTA)TM, the consumer sector alone directly generated $1.9 trillion in 2015, which directly accounted for 5.2 percent of the U.S. gross domestic product (GDP). A few more examples further illustrate the rapid growth of the electronics sector…
With this worldwide growth in electronics and the need to miniaturize while increasing copper density, coupled with the need to build higher Q inductors with nominal losses, the demand for preformed Litz wire is tracking along a similar growth trend.
For those not familiar with the fundamental characteristics of Litz wire, consider these facts.
Litz wire gets its name from the German litzendraht, which means braided or stranded wire. Litz wire is made by weaving or twisting many thin strands of insulated wire together in a specific pattern. Litz wire was introduced and commercialized in the United States beginning in 1898 by New England Wire Technologies.
Litz wire consists of a number of individually insulated magnet wires twisted or braided into a uniform pattern. In some Litz constructions twisted bundles are joined with other bundles, all of which are then twisted into the final product.
Litz wire’s unique twisting places each strand at the outside periphery of the conductor and at its center in equal measure. This unique twisting method, plus carefully selected wire diameter, gives Litz wire the ability to minimize losses from two sources: skin effect and proximity effect.
Designers can virtually eliminate the skin effect with Litz wire. The key is to choose the diameter of individual wire strands twisted into the Litz construction that are similar to the skin depth for the given frequency. Doing so causes current to flow through nearly the entire cross section of each wire, thus minimizing AC resistance and heat losses.
The unique Litz wire twisting pattern places each strand nearly equally at the inside and outside of the cable, which equalizes the flux linkages and reactances of the individual strands. This causes the current to spread uniformly throughout the conductor. The resistance ratio (AC to DC) then approaches unity, which is especially desirable in high-Q circuit applications.
Litz wire is made with individually insulated strands that may range from 28 to 48 AWG. Common magnet wire film insulations—polyvinylformal, polyurethane, polyurethane/nylon, solderable polyester, solderable polyester/nylon, polyester/polyamide-imide and polyimide—are normally used to insulate each strand.
The outer insulation and the insulation on the component conductors, in some styles, may be servings or braids of nylon, cotton, Nomex®, fiberglass or ceramic. Polyester, heat sealed polyester, polyimide and PTFE tape wraps along with extrusions of most thermoplastics are also available as outer insulation if the applications dictate special requirements for voltage breakdown or environmental protection.
Preformed Litz wire is initially constructed with a round cross section. Formed constructions are those in which the bundle of wire is reshaped and formed to create a geometry other than the original round construction. Special care must be taken to reshape the bundle without damaging the outer film insulation on the individual strands of wire. Typical shapes for formed Litz wire are rectangular, square and keystone.
Litz wire is manufactured in nine different styles. Types 4, 5 and 6 Litz wire constructions all utilize at least one inert core and are used primarily in tuning circuitry for high power radio transmitters. The smaller constructions of Litz wire, Types 1 and 2, are typically used in high Q circuitry such as toroidal coils and transformers. The larger Type 2 and Type 3 Litz wire designs have greater current carrying capacities necessary for high frequency power supply, inverter and grounding applications. Type 7 are braided and Type 8 are twisted and compressed/formed – both into a rectangular profile. Type 9 is a coax-style construction used to carry high frequency electrical signals with low losses and engineered to block signal interference. (Learn more here).
The high efficiency characteristics of Litz wire make it a preferred choice in the application areas listed here.
Litz Applications | For Example... |
---|---|
Wireless Power Transfer | Vehicle Charging Systems |
High Q Circuitry | Tuning Coils |
Transformers & Torodial Transformers | Power Transformers |
Inductors, Chokes | Solar Inverters, Motor Drives (VFDs) |
Motors & Generators, Linear Induction Motors, Permanent Magnet Motors | Maglev Trains, Vehicle Propulsion, Oil & Natural Gas Drilling, Wind Turbines |
High Frequency Power Supplies | Coils & Transformers |
Inverters | DC to AC |
Low Impedance Grounding | Industrial Machinery |
DC to DC Converters | Electric Vehicles, Automotive, Medical Electronics |
Induction Heating Coils | Induction Cooktops, Sealing Bottles, Mold Preheat Before Plastic Injection |
Ballast | Fluorescent Lighting |
Propagation of High Frequency Power Litz Lead Wire | Leads to Thin Film Deposition Equipment, MRI, Induction Heating |
Flywheel Energy Storage | Energy Storage |
Plasma Containment Coils | Stellarator, Fusion Experiments |
Specialty Audio | High Fidelity Speaker Wire, Audio Interconnect |
With Litz being manufactured in nine styles, Type 8 and Type 2 constructions are most often used to manufacture preformed Litz wire. Type 8 uses insulated strands that are formed into a square or rectangular cross section. The more economical Type 2 features bundles of twisted wires with each bundle again twisted together, then covered with an optional outer insulation. Both Type 2 and Type 8 can be formed into square, rectangular and keystone cross sections.
Type 2 is typically used in high Q circuitry, such as toroidal coils and transformers at frequencies up to around 1 MHz. The heavier gauge Type 2 designs have greater current carrying capacities necessary for high frequency power supplies, power conditioning, inverter and grounding applications. Type 2 is well suited for a wide range of uses and is rapidly becoming a first choice for magnetic device design.
The majority of Litz wires are coated with an insulation using solderable polyurethane, solderable polyurethane/nylon or other coatings. For the few specialty Litz constructions that use high temperature enamel insulation, a number of simple processes allow for easy removal of the enamel that makes those constructions easily solderable. (Learn more here and here).
Initially, there two key questions to answer in choosing the type of Litz wire best suited for a given application. First is the RMS current flow expected, which helps determine the wire gauge and construction used.
Second is the frequency to be used in the application. It’s important to choose a wire gauge for the individual strands that are comparable in diameter with the skin depth at the frequency to be used. The table illustrates how various frequencies map (roughly) into AWG wire diameters. However, when cost is an issue, using a lower cost, heavier gauge wire with a diameter up to about twice the skin depth seldom introduces significant losses below around 1 MHz.
60 Hz to 1 kHz | 28 AWG |
1 kHz to 10 kHz | 30 AWG |
10 kHz to 20 kHz | 33 AWG |
20 kHz to 50 kHz | 36 AWG |
50 kHz to 100 kHz | 38 AWG |
100 kHz to 200 kHz | 40 AWG |
200 kHz to 350 kHz | 42 AWG |
350 kHz to 850 kHz | 44 AWG |
850 kHz to 1.4 MHz | 46 AWG |
1.4 MHz to 2.8 MHz | 48 AWG |
However, these two factors do not identify the precise Litz construction needed. Further calculations are necessary to meet design goals for the project. Charles Sullivan (Dartmouth College) and Richard Zhang (MIT) offer a simplified approach for choosing the number and diameter of strands in Litz wire, and they show how to select the number of strands or sub-bundles to combine at each twisting operation.
Or, for more tailored help in selecting Litz wire, our Customer Engineering team can help specify the best Litz configuration for a given application. Such consultation often leads to discussion about the project; collaboration on the geometry of the coil; and, perhaps on the use of specific computer modeling software tools and other resources.
While Litz is more costly than plain magnet wire, there are clear cases that call for Litz wire.
Preformed Litz has a small price delta when compared to round Litz wire. However, preforming gives an even smaller, lighter, more efficient device (calculated to be about 10% better area usage, energy efficiency, or a combination of both) than round Litz wire. If achieving a 10% gain in performance is significant in the application, the price uptick for preformed Litz will have little impact on build cost versus regular, round Litz.
The manufacture of preformed Litz wire is a specialty that New England Wire has perfected after delivering round Litz constructions to the electronics industry for more than a century. In recent years the company has developed proprietary fabrication techniques that reliably process round Litz constructions into various cross sectional geometries—all without damage to individual strands or their insulation, and backed by the company’s extensive quality assurance programs.
Preformed Litz wire elevates your design not only by increasing the efficiency of your magnetic device. For engineering teams that use the “Design for Excellence” (DFX) approach, the use of preformed Litz wire can impact maintainability, manufacturability, economy, reliability and serviceability. Whether your magnetic device design challenge requires low losses, high Q, or small form factor, contact us and tap into our decades of knowledge.
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Please note, this is not a listing of available part numbers for purchase, but rather an overview of Litz wire, it’s types, benefits, applications, and material/design selection assistance.
A common question asked of the sales and engineering staff at New England Wire Technologies by those unfamiliar with our company is why a custom cable solution should be considered when there are so many off the shelf options out there. This is a very reasonable question and in some cases a standard product does make sense. However, when electrical device and component manufacturers stop to consider what properties would be ideal to meet the demanding requirements of their application and what level of service and quality they expect from their suppliers, the advantage of a custom cable solution from New England Wire Technologies becomes apparent.
The most immediate benefit of a custom solution is the knowledge and design assistance that the staff at New England Wire can provide for your project. Rather than spending days or weeks researching material, electrical and mechanical properties to understand your design options and then pouring through catalogs or calling vendors to try to find a part number close to what you actually need, you can simply go to our Contact Us form to upload a document, describe your requirements, or send an image of an existing cable. Our engineering staff will use their knowledge and experience to design an ideal solution optimized for your exact application. When new requirements, additional options, or added capabilities become necessary, a custom option is quickly adaptable to your changing needs.
Every aspect of a cable is customizable. A standard product will often use coarse stranding, stiff insulation and shielding, and low temperature materials to reduce cost. In addition, the exact size, number, or composition of components needed may not be an option, limiting your selection to an oversized, overweight, or otherwise inexact solution. With a custom cable from New England Wire Technologies you can select the exact components needed for your application to minimize size and weight. We will work with you to determine appropriate conductor stranding for the level of flexibility needed and the ideal conductor material or plating option to balance conductivity, flex life, temperature rating, etc. New England Wire stocks over one hundred extrusion compounds for use as insulation and cable jacketing, combined with a variety of film and textile options to support an incredible range of product requirements. These include the specific temperature and voltage ratings required for your application, flame resistance, flexibility, biocompatibility, low smoke, chemical resistance, toughness, UV resistance, and many more. Shielding is also customizable with the proper selection of braided, spiral, foil, or a combination to balance electrical shielding effectiveness with mechanical or diameter requirements. These are just a sampling of the design options and potential advantages that a custom cable solution from New England Wire Technologies can provide.
Why a custom cable? Perhaps that is a question best answered by the thousands of satisfied customers around the world using New England Wire products. Whether it is the right option for you; that is a question we would love to help you figure out…contact us today to discuss your wire and cable needs.
By Shanna Hale
Motors, induction heaters, transformers and other devices with wound wire coils pose a problem to designers. Because they are not “perfect,” they suffer losses that show up as heat. New England Wire Technologies has developed a technology that saves time, money and gives design engineers and manufacturers proven, UL-listed solutions for building safer wire coils.
Wire heats up when an electrical current passes through it due to its natural resistance. Because coils require long lengths of wire, heat produced due to resistance can be a significant factor. Increasing the wire gauge reduces resistance and resulting heating, but also increases the cost, size and weight of the coil. The amount of heat produced is in direct relation to the wire’s natural resistance.
However, natural resistance isn’t the only reason coiled wire heats up. A coil packs a lot of copper into a confined space. When layers of conductors are wound over one another, they can’t cool as efficiently because heat from one part of the wire will radiate to other parts of the wire and the winding components, rather than dissipate primarily into the open air. Further, heated air that may be flowing over one part of the coiled wire may flow over another part of the coil instead of away from the coil.
In alternating current applications, the “skin effect” can significantly contribute to unwanted heat. At operating frequencies of 60 Hz and above, current tends to flow along the surface of a conductor due to eddy currents induced by the changing electromagnetic field that alternating currents produce. Most current flow occurs along the surface of the conductor down to its’ skin depth. It is only this area of the conductor that is transmitting the electrical current. With most of the current flowing through only a small cross-section of the wire, the skin effect increases the wire’s AC resistance in direct proportion to the frequency of the current. For example, with a 5-kHz frequency applied through a copper magnet wire, the current density is largely confined to the outer one millimeter of the conductor. At a frequency of 1 MHz, skin depth is approximately 0.076mm.
The “proximity effect” further contributes to winding wire inefficiency for electrical conductors used as winding wires in alternating current applications. If two wires carrying the same alternating current lie parallel to one another, the AC current creates a magnetic field which induces eddy currents in adjacent conductors that alters the overall distribution of current flowing through them. The net effect of the current is concentrated only in the areas of the conductor furthest away from nearby conductors carrying current in the same direction. The proximity effect and skin effect can make solid strand winding wires very inefficient and can cause significant heat in a winding.
Excessive heat from any of these sources can damage the insulating material used to keep each coil winding insulated from the components used in the winding. Use of an Electrical Insulation System (EIS) will help to prevent such damage from occurring.
An EIS is a combination of electrical insulating materials (EIM) that have been tested for compatibility at specific maximum temperatures. Engineers usually choose EIM’s (magnet wire film insulations, encapsulants, varnishes, etc.) based upon expected hot spot temperature design limits. However, at temperatures greater than about 100°C, individual insulating materials begin to react chemically with one another. Such reactions can affect dielectric strength, flame resistance, ignition resistance and lead to premature product failure, fire hazards and product liability issues. Today, Electrical Insulation Systems play an important role in product safety and have been formalized as global industry standards.
These chemical reactions and incompatibilities can’t be predicted through mathematical modeling or the stated temperature rating of the various insulating materials. EIM’s need to be tested over long periods of time (usually up to seven months) at three different temperatures to determine the maximum temperature that the combination of materials can safely operate. During the full thermal aging process samples are subjected to a cycling program that includes mechanical stress, cold shock, and moisture exposure. This sort of rigorous long term testing is expensive to conduct. Chemical compatibility testing (CCT) is usually required to add non-electrical insulating materials (NIM) that are used typically in mechanical or thermal conduction capacities that a customer wants to use in conjunction with an existing electrical insulation system. Examples of NIM’s include balancing compounds, potting compounds, sleeving and tubing, spacers, wedges, tie cords, etc. This is under the scope of UL standard 1446 and a short duration (two week) test is required.
NEWT offers a versatile, pre-approved, Electrical Insulation System recognized by Underwriters Laboratories for use in the construction of transformers, motors and coils. The NE-F1 electrical insulation system from NEWT is Class F (155°C) rated and has an OBJS2 file number of E231977.
To view NEWT’s full NE-F1 table of offerings, click here.
The NE-F1 system eliminates the need for lengthy and expensive component testing required to develop your own EIS. It’s versatile and provides a large selection of EIM’s and NIM’s to support most any application.
NEWT’s manufacturing expertise dates back to the 1890’s when we were the first company in the USA to manufacture Litz wire on a commercial basis. With our extensive experience with UL and other regulatory agencies, our NE-F1 system provides the necessary approvals to give our customers a turnkey EIS that can be used across a wide range of design projects.
NEWind® is special winding wire that replaces traditional forms of single end copper or magnet wire. NEWind® results in more efficient devices that you bring to market. Your products can be smaller and less costly to make and you’ll get them to market much faster because you don’t have to endure long months of testing. NEWind® has been tested in NEWTC’s NE-F1 (155°C) electrical insulation system as an EIM of the NE-F1 Class F (155°C) EIS. It was developed to save time in winding coils, to reduce coil size, and to cut costs. With NEWind®, no additional ground or inter-winding insulation is required to separate NEWind® from other enameled magnet wire windings, or from grounded or dead metal. This allows for a faster winding assembly process and reduces the number of inventoried materials needed to manufacture the product.
In addition to Underwriters Laboratories (UL), other agencies such as the International Electrotechnical Commission (IEC), and Verband der Elektrotechnik (VDE) have published their own testing standards and requirements that manufacturers can use to verify the safety and compatibility of winding wires in the intended application. NEWind® is compliant with the following standards:
NEWind® constructions offer a choice of three extruded fluoropolymers – ETFE, FEP, and PFA and can be provided using any conductor material. The extruded layers can be provided as Basic Insulation (one layer), Supplementary Insulation (two layers), or Reinforced Insulation (three layer). Supplementary and reinforced insulations assure defects in any one layer does not compromise the insulating ability of the composite extrusions. As a result, motors and transformers can be manufactured without additional insulation, thus reducing their cost and size.
Litz wire is made by weaving or twisting many fine gauge individually insulated magnet wires together in a specific pattern that distributes alternating current flow equally through the entire cross section of the conductor. As a result, litz wire minimizes two kinds of AC losses—skin and proximity effects—which makes the conductor inefficient and generate significant unwanted heat in a winding. Your winding will operate more efficiently with litz wire, especially at higher operating frequencies. It also makes your winding easier to work with because you don’t have to use interleaving insulation; it’s already part of your winding wire.
NEWind® Litz constructions are especially suited for the following applications:
• Induction heating
• Transformers
• Electric motors
• Military applications
• High end audio
• Medical winding applications (electro-surgical tools, for example)
• Power generation
• Pumps
• Domestic appliances
• Automotive
• Relays
• Solenoids
• Electromagnets
• Inductors
• Control devices
You can develop your own EIS at substantial time and cost. Or, you can adopt an approved NE-F1 Class F (155°C) system from NEWT. You’ll not only enjoy the benefits outlined above but also receive expert support if you may be unsure how EIS technology works. We look forward to sharing our expertise with you. Please contact us to learn how you can begin using this technology today.
Editor’s Note: Article contributed by James Clough and Richard Trahan, Design Engineer staff members at New England Wire Technologies.
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