Product Catalogue

About Us Parashar Vidyut Udyog, an enterprise registered under government of India’s ministry of micro, small and medium enterprises is located in NOIDA, the modern industrial city in Delhi’s National Capital Region, is today India’s most reputed manufacturer of Litz for the HF and Induction heating components and Electrical & Electronics industry.

We are known for our HF Litz expertise, our development and manufacturing capabilities thereof. Beside that we are known for Tinsil copper/silver wire for speaker industry and flexible wires/PVC insulated cables for electrical and electronics industry. Our focus on quality, our R & D capabilities, market responsiveness and the ability to scale up manufacturing capacities for meeting clients’ needs distinguishes us, making us a preferred supplier for HF Litz Wire in electrical & Electronic industry.

Parashar Vidyut Udyog is a highly proactive, professional organization that seeks to understand the market, identify opportunities and develop capabilities to create competitive advantage for its customers.

A proactive, forward thinking organization which has eliminated all odds in creating a global level manufacturing setup, Parashar Vidyut Udyog is today moving forward with a well-defined, time bound executable plan to establish a global footprint for advanced HF Litz Wire.

Our dedicated and efficient personnel that include engineers, developers and operators among several others work in complete unison fulfilling every demand of the customer in the most credible manner. Our adequate quality testing facility includes various equipment & tools to test the products on standard parameters. Parashar Vidyut Udyog business philosophy can be summed up in just two words – Customer Focused. This is probably the reason why today, Parashar Vidyut Udyog partners with practically every leading global player in the HF Transformer and Induction heating components and Electrical & Electronics industry.

We are aggressively working to increase our product offerings with an expanded range of HF Litz Wires. In order to fulfill customer expectations and trust, and to achieve recognition for its value to industry, Parashar Vidyut Udyog, in addition to establish and complying with the stringent standard, has been awared to certification for global standards like ISO 9001:2015 Quality Management System.

Parashar Vidyut Udyog has built up an organization which continues to address divergent issues that her partners face. Customer Focused is not just a philosophy at Parashar Vidyut Udyog but a well-entrenched realization down to the operator level, that, our very existence is the result of trust imposed by our customers on us. Product Catalogue

Introduction to Litz Wire

Litz wire conductors are beneficial for reducing AC losses in high frequency windings. Parashar Vidyut udyog offers litz wire in many constructions with multiple layers of insulations to meet meet voltage withstand requirements.

Litz wire is a bunch of several strands of enamelled copper wire. It’s construction vary from a simple bunch of conductor or multiple cores laid up together. The Litz wire is designed to reduce the and proximity effect losses in conductor at high frequencies up to 1 MHz. Litz wires are typically used in HF , HF , electronic chokes, Toroidal coils, proximity switch, relays, Induction heating, induction, motors, sonar equipment, Inverters, power supply units, SMPS, ultrasonic generators, medical , sterlization equipment, AC-DC converters, Identification systems, magnetic loading, Hearing aids, repeating coils, deflexion yokes, fluorescent lamp ballast, solar inverters, wind power generators, UPS, Eximer Laser and in many other high frequency applications.

Litz Wire sizes are generally expressed in abbreviated format i.e. N/XX, Where N equals the number of strands, and XX is the conductor diameter of each strands in SWG/AWG/mm. For example, a typical size of a Litz wire would be expressed as "90/46 SWG" or 90 strands of 46 SWG (0.061 mm).

We have a range of Litz Wire and are manufactured from enamelled copper wires made up of high quality copper rods and modified polyurethane, polyesterimide wire enamels as basecoat and aromatie / polyamide as top coat. These are suitable for thermal class 155°C to 240°C. These wires have very good self-fluxing, solderability and high thermal properties.

Litz wire are avialable in two forms Served or Unserved. Serving means that the bunched enamelled copper wire have a outer protective covering of one or two lapping of silk yarn, nylon, polyester, Cotton or Nomex (High temperature aramid). Typically serving is used to protect thin film insulation of the individual strands. The serving adds about 0.06 mm to the diameter of Litz Wire. The first lapping of serving is applied to the bunched wires in a direction opposite to the twist of the bunched wires. If a second lapping is to be applied it shall be in the opposite direction to the first lapping. The covering is uniform in quality and each lapping is even and uniform. Product Catalogue

Reason of using Litz Wires in high frequency applications. The DC (0 Hz) resistance of a conductor depends on its cross sectional area. A conductor with a larger area has a lower resistance. The resistance also depends on frequency because the effective cross section area changes with frequency. As frequency increases, conduction begins to move from an equal distribution through the conductor cross section toward existance almost exclusively near the surface. Depending on the conductor bulk resistivity at sufficiently high frequency all the RF current is flowing within a very small thickness at the surface. Furthermore the current concentrates nearest to the surface that abuts the highest relative dielectric contant. So round conductors such as wire or cables donot conduct much current near their axis, So the central material is not used effectively.

One technique to improve the effeciency is to reduce amount of material that does not carry current by making the conductor of hollow tubing. The large surface area of the tube conducts the current with much less resistance than a solid wire with the same cross sectional area would. The tank coils of high power radio transmitters are often made of copper tubing, silver plated on the ouside to reduce resistance.

Litz wire is another method which employs a standard wire with individually insulated conductors (forming a bundle). Each thin conductor is less than a skin depth so an individual strand does not suffer a skin effect loss. The strands must be insulated from each other - otherwise all the wires in the bundle would short together, behaves like a single large wire, and still have skin effect problem. Furthermore the strands cannot occupy the same radial position in the bundle over long distances. The electromagnetic effect that cause the skin effect would still disrupt conduction. The weaving or twisting pattern of the wire in the bundle is designed so that the individual strands are on the ouside of the bundle for a distance and are inside for a distance. If each strand has a equally among every strand within the cable.

In case of multiple wires or multiple turns, such as windings in transformers and inductors, the proximity effect causes losses to increase at high frequency even sooner and more rapidly than does skin effect. Proximity effect is the tendency for curent to flow in loops or concentrated distributions due to presence of magnetic fields generated by nearby conductors. In transformers and inductors, proximity effect losses are generally more significant than skin effect losses. In Litz Wire winding proximity effect may be subdivided in to internal proximity effect (the effect of other currents within the bundle) and outer proximity effect (the effect of the current in other bundles). The Litz wires are twisted or weaved just to ensure that the strand currents are equal. Where a simple bunched conductor wire can accomplish this adequately. Where skin effect would be a problem more complex Litz wire constructions can be used to ensure equal strand current.

Litz wire is very effective below 500 KHz. It is rarely used above 2 MHz because at frequencies above 1 MHz the benefit becomes gradually offset by the capacitive build up between the strands. Litz wire has a higher impedance per unit cross sectional area but Litz Wire can be used at thicker cable sizes hence reducing or maintaiing cable impedance at higher frequeny. Product Catalogue Benefits of Litz Wire * Reduce A.C. Losses in high frequency winding. * Increased Effeciency. * Mitigation of Skin effect. * Mitigation of Proximity Effect. * Minimum losses. * Lowered operating temperatures. * Reduced footprint of final product. * Substancial weight reduction. * Avoidance of "Hot Spots".

Application of Litz Wire * High Frequency Transformers * Toroidal Coils * Stator Winding * High Frequency Inductors * Power Transformers * Inverters * Motor Generators * Hybrid Transportation * Wind Turbine Generators * Communication Equipments * Marine Acoustic Control Systems * Induction Heating Equipments * Sonar Equipments * Radio Transmitter Equipments * Switch Mode Power Supply * Ultrasonic Equipments * Linear Motors * Sensors * Antenas * Grounding Applications * Wireless Power Systems * Electric Vehicle Chargers * High Frequency Chokes * High Frequency Motors * Medical Sterlization Equipments * Medical Device Chargers * High Q Circuitry * Tuning Circuitry in High Power Radio * Flywheel Energy Storage * Plasma Containment Coils * Hearing Aids * Relays * Eximer Laser * Welding Machine Product Catalogue * Welding Machine

Litz Wire Types and Constructions

Type 1 Litz construction Type 2 Litz construction Type 3 Litz construction features a single twisting features bundles of features insulated bundles operation with optional twisted wire twisted of twisted wire twisted outer insulation. together with optional together with optional outer insulation. outer insulation.

Type 4 Litz construction Type 5 Litz construction Type 6 Litz construction features bundles of features insulated bundles features bundles of Type 4 twisted wire twisted of Type 2 wire twisted wire twisted around a around a central fiber around a fiber core. fiber core. core.

Type 7 Litz construction Type 8 Litz construction features insulated wire features single insulated braided and formed into a strands twisted and rectangular profile. compressed into a rectangular profile. Product Catalogue Film Insulations Film Insulation Thermal Range of Advantages Considerations Material Rating wire (φ) * Excellent electrical properties with * Not recommended for Class 155°C high Q coils. applications with the possibility MW 79-C * Easily solderable 390°C / 360°C of severe thermal overload. 0.04 to Polyurethane * Excellent film adhesion and flexibility. 1.10 mm Class 180°C * Good moisture and chemical MW 82-C resistance

* Good electrical properties * Not recommended for * Easily solderable 430°C / 390°C applications with the possibility Class 155°C * Excellent film adhesion and flexibility. of severe thermal overload. MW 80-C Polyurethane- 0.04 to * Improved chemical and mechanical * Nylon topcoat is hygroscopic. Nylon 1.10 mm resistance from Nylon topcoat. Class 180°C * Nylon overcoat provides low MW 83-C coefficient of friction.

* Excellent abrasion resistance. * Must be stripped before * Excellent compatibility with soldering Polyvinyl Class 155°C 0.04 to transformer oils. * Should be annealed before Formal MW 15-C 1.10 mm * Good electrical properties. application varnish. * Used in cryogenic applications. * Solderable 470°C * Low abrasion resistance * Excellent thermal properties. compared to Nylon and amide * Good electrical properties. imide topcoat materials. Solderable Class 180°C 0.04 to * Good compatibility with varnishes and * Preheat before varnishing is polyester MW 77-C 1.10 mm solvants. recommended. * Improved thermal overload. * Good moisture resistance. * Solderable 470°C * Nylon topcoat is hygroscopic. * Excellent thermal properties. * Preheat before varnishing is * Good electrical properties. recommended. Solderable * Good compatibility with varnishes and Class 180°C 0.04 to polyester- solvants. MW 78-C 1.10 mm Nylon * Improved thermal overload. * Good moisture resistance. * Nylon topcoat provides low coefficient of friction. * Excellent flexibility and abrasion * Must be stripped before resistance . soldering Polyester Class 200°C 0.04 to * Excellent Thermal Overload. * Not recommended for use in (Amide) (Imide) MW 74-C 1.10 mm * Excellent dielectric strength. oil-filled transformers. * Excellent moisture resistance. * Preheat before varnishing. * Good chemical resistance Product Catalogue * Excellent flexibility and abrasion * Must be stripped before resistance . soldering Polyester / Class 200°C 0.04 to * Excellent Thermal Overload. * Preheat before varnishing. Polyamideimid MW 35-C 1.10 mm * Excellent dielectric strength. e overcoat * Excellent moisture resistance. * Good chemical resistance * Excellent flexibility. * Must be stripped before * Excellent Thermal Overload. soldering. * Excellent radiation resistance. * Must be annealed before Class 240°C 0.04 to Polyimide * Excellent chemical compatibility. varnishing. MW 16-C 1.10 mm * High dielectric strength. * Will solvent craze. * Adequate abrasion rsistance. * Low outgas

Litz Wire Outer Insulation (Fibre)

Recommended Insulation Max. Operating Advantages Disadvantages (Fibre) Temperature

* Good space factor Nylon 155°C * Excellent abrasion resistance * Hygroscopic * Solderable

* Good space factor * Poor elasticity. Natural Silk 80°C * Excellent abrasion resistance * Can be weakened if exposed In heat * Solderable for a long time.

* Solderable * Better space factor than Cotton or * Good abrasion resistance Polyester 155°C Glass but poorer space factor than * Slightly higher maximum operating Nylon. temperature than Nylon.

* Good space factor. * Non-solderable. Nomex (High * Good electrical properties at high 250°C * Higher cost than other fibers. Temp. Aramid) temperatures.

* Low cost serving. * Poor space factor compared to Cotton 105°C * Good resistance to abrasion. Nylon or Celanese. * Non-solderable. Product Catalogue

Litz Wire Outer Insulation (Tape)

Recommended Max. Insulation (Tape) Characteristics Operating Temperature

Polyester (PET) 135°C * High dielectric strength

Myler (Heat Sealable * Good abrasion often used as binder or moisture barrier 155°C Grade) under extruded jackets and textile serves or braids.

* Excellent thermal properties. 200°C * Excellent electrical properties. Nomex (Aromatic (Up to 220°C under * Excellent compatibility with varnishes, adhesives and Polyamide) certain conditions transformer fluids. * Thinner grades are flexible. * Good resistance to tearing and abrasion.

Polyimide Kapton 240°C * Very high dielectric strength. (Heat sealable & (Up to 400°C under * Very good chemial resistance. adhesive certain conditions.) * UL 94 V-0 flame rating. grades available) * Excellent mechnical properties.

* Fire resistance property. Glass Mica Cable Tape 180°C * Can withstand very high environmental temperature up (GMCAB Tape) to 950°C in certain condition.

Extruded Insulations for Litz Conductor

Insulation Recommended Max. Advantages Disadvantages (Fibre) Operating Temperature * Very good dielectric properties. PE / PP 250°C * Litz Coax / Triax. * Outstanding water resistance.

* Least expensive. * Winding Wire * Excellent flame resistance. PVC 105°C * High frequency interconnect. * Excellent flexibility. * Primary in multiconductor * Medical grades

* Excellent abrasion resistance. * Very good flexibility. Polyurethane 90 to 105°C * High frequency interconnect. * Can be coiled. * Halogen free Product Catalogue

Round Litz Wire (Type-1 & Type-2)

Number SWG of Film Outer Nominal Maximum DC Construction of Wires Wires Coating Insulation OD (mm) Resistance Ω/Km

3 / 36 3 36 S SS 0.520 205.0 4 / 36 4 36 S SS 0.595 155.0 5 / 36 5 36 S SS 0.695 122.0 6 / 36 6 36 S SS 0.755 105.0 7 / 36 7 36 S SS 0.750 90.0 8 / 36 8 36 S SS 0.860 80.0 9 / 36 9 36 S SS 0.905 70.0 10 / 36 10 36 S DS 0.950 65.0 12 / 36 12 36 S DS 1.050 55.0 16 / 36 16 36 S DS 1.200 40.0 20 / 36 20 36 S DS 1.350 35.0 25 / 36 25 36 S DS 1.500 25.0 27 / 36 27 36 S DS 1.550 23.0 32 / 36 32 36 S DS 1.690 20.0 36 / 36 36 36 S DS 1.800 19.0 40 / 36 40 36 S DS 1.900 18.0 50 / 36 50 36 S DS 2.100 15.0 60 / 36 60 36 S DS 2.300 13.0 63 / 36 63 36 S DS 2.350 11.0 80 / 36 80 36 S DS 2.650 9.0 81 / 36 81 36 S DS 2.650 8.0 100 / 36 100 36 S DS 2.950 7.0 120 / 36 120 36 S DS 3.200 6.0 135 / 36 135 36 S DS 3.350 5.0 180 / 36 180 36 S DS 3.900 3.50 200 / 36 200 36 S DS 4.100 3.25 250 / 36 250 36 S DS 4.600 2.75 260 / 36 260 36 S DS 4.650 2.50 320 / 36 320 36 S DS 5.200 2.00 400 / 36 400 36 S DS 5.750 1.75 3 / 38 3 38 S SS 0.400 330.0 4 / 38 4 38 S SS 0.450 250.0 5 / 38 5 38 S SS 0.500 200.0 6 / 38 6 38 S SS 0.550 170.0 7 / 38 7 38 S SS 0.600 145.0 8 / 38 8 38 S SS 0.700 125.0 9 / 38 9 38 S SS 0.750 110.0 10 / 38 10 38 S SS 0.800 100.0 12 / 38 12 38 S SS 0.850 85.0 16 / 38 16 38 S DS 0.950 65.0 20 / 38 20 38 S DS 1.050 50.0 25 / 38 25 38 S DS 1.250 40.0 27 / 38 27 38 S DS 1.300 39.0 32 / 38 32 38 S DS 1.350 35.0 Product Catalogue Number SWG of Film Outer Nominal Maximum DC Construction of Wires Wires Coating Insulation OD (mm) Resistance Ω/Km 36 / 38 36 38 S DS 1.450 30.0 40 / 38 40 38 S DS 1.500 27.0 50 / 38 50 38 S DS 1.700 22.0 60 / 38 60 38 S DS 1.850 18.0 63 / 38 63 38 S DS 1.900 17.0 80 / 38 80 38 S DS 2.100 15.0 81 / 38 81 38 S DS 2.150 14.0 100 / 38 100 38 S DS 2.350 12.0 120 / 38 120 38 S DS 2.600 10.0 135 / 38 135 38 S DS 2.700 8.0 180 / 38 180 38 S DS 3.150 6.5 200 / 38 200 38 S DS 3.300 5.5 250 / 38 250 38 S DS 3.700 4.5 260 / 38 260 38 S DS 3.750 4.0 320 / 38 320 38 S DS 4.150 3.5 400 / 38 400 38 S DS 4.650 2.75 3 / 40 3 40 S SS 0.350 505.0 4 / 40 4 40 S SS 0.400 380.0 5 / 40 5 40 S SS 0.450 305.0 6 / 40 6 40 S SS 0.500 255.0 7 / 40 7 40 S SS 0.500 220.0 8 / 40 8 40 S SS 0.550 192.0 9 / 40 9 40 S SS 0.600 170.0 10 / 40 10 40 S SS 0.600 153.0 12 / 40 12 40 S SS 0.650 127.0 16 / 40 16 40 S SS 0.800 97.0 20 / 40 20 40 S DS 0.900 78.0 25 / 40 25 40 S DS 1.000 65.0 27 / 40 27 40 S DS 1.050 60.0 32 / 40 32 40 S DS 1.150 52.0 36 / 40 36 40 S DS 1.200 47.0 40 / 40 40 40 S DS 1.250 42.0 50 / 40 50 40 S DS 1.400 35.0 60 / 40 60 40 S DS 1.500 30.0 63 / 40 63 40 S DS 1.550 27.0 80 / 40 80 40 S DS 1.750 22.0 81 / 40 81 40 S DS 1.750 21.0 100 / 40 100 40 S DS 1.950 18.0 120 / 40 120 40 S DS 2.100 14.0 135 / 40 135 40 S DS 2.250 13.0 180 / 40 180 40 S DS 2.550 10.0 200 / 40 200 40 S DS 2.700 9.0 250 / 40 250 40 S DS 3.000 8.0 260 / 40 260 40 S DS 3.050 7.0 320 / 40 320 40 S DS 3.400 6.0 400 / 40 400 40 S DS 3.800 5.0 3 / 42 3 42 S SS 0.300 725.0 4 / 42 4 42 S SS 0.350 545.0 Product Catalogue Number SWG of Film Outer Nominal Maximum DC Construction of Wires Wires Coating Insulation OD (mm) Resistance Ω/Km 5 / 42 5 42 S SS 0.350 435.0 6 / 42 6 42 S SS 0.400 365.0 7 / 42 7 42 S SS 0.400 315.0 8 / 42 8 42 S SS 0.450 275.0 9 / 42 9 42 S SS 0.500 245.0 10 / 42 10 42 S SS 0.500 220.0 12 / 42 12 42 S SS 0.550 185.0 16 / 42 16 42 S SS 0.650 140.0 20 / 42 20 42 S SS 0.750 112.0 25 / 42 25 42 S SS 0.850 90.0 27 / 42 27 42 S DS 0.900 85.0 32 / 42 32 42 S DS 0.950 72.0 36 / 42 36 42 S DS 1.000 64.0 40 / 42 40 42 S DS 1.050 58.0 50 / 42 50 42 S DS 1.150 46.0 60 / 42 60 42 S DS 1.300 39.0 63 / 42 63 42 S DS 1.350 38.0 80 / 42 80 42 S DS 1.450 30.0 81 / 42 81 42 S DS 1.500 29.0 100 / 42 100 42 S DS 1.650 25.0 120 / 42 120 42 S DS 1.800 20.0 135 / 42 135 42 S DS 1.900 18.0 180 / 42 180 42 S DS 2.200 15.0 200 / 42 200 42 S DS 2.300 13.0 250 / 42 250 42 S DS 2.500 10.0 260 / 42 260 42 S DS 2.600 9.5 320 / 42 320 42 S DS 2.900 7.5 400 / 42 400 42 S DS 3.200 6.5 600 / 42 600 42 S DS 3.950 3.9 660 / 42 660 42 S DS 4.150 3.50 1000 / 42 1000 42 S DS 5.100 2.35 1050 / 42 1050 42 S DS 5.200 2.25 3 / 44 3 44 S SS 0.250 1200.0 4 / 44 4 44 S SS 0.250 900.0 5 / 44 5 44 S SS 0.300 700.0 6 / 44 6 44 S SS 0.300 600.0 7 / 44 7 44 S SS 0.350 500.0 8 / 44 8 44 S SS 0.400 450.0 9 / 44 9 44 S SS 0.400 400.0 10 / 44 10 44 S SS 0.400 375.0 12 / 44 12 44 S SS 0.450 300.0 16 / 44 16 44 S SS 0.500 235.0 20 / 44 20 44 S SS 0.600 200.0 25 / 44 25 44 S SS 0.700 150.0 27 / 44 27 44 S SS 0.700 145.0 32 / 44 32 44 S DS 0.750 120.0 36 / 44 36 44 S DS 0.800 105.0 40 / 44 40 44 S DS 0.850 95.0 Product Catalogue Number SWG of Film Outer Nominal Maximum DC Construction of Wires Wires Coating Insulation OD (mm) Resistance Ω/Km 50 / 44 50 44 S DS 0.950 75.0 60 / 44 60 44 S DS 1.050 65.0 63 / 44 63 44 S DS 1.050 60.0 80 / 44 80 44 S DS 1.200 50.0 81 / 44 81 44 S DS 1.200 48.0 100 / 44 100 44 S DS 1.300 40.0 120 / 44 120 44 S DS 1.450 35.0 135 / 44 135 44 S DS 1.550 30.0 180 / 44 180 44 S DS 1.750 25.0 200 / 44 200 44 S DS 1.850 20.0 250 / 44 250 44 S DS 2.050 17.0 260 / 44 260 44 S DS 2.100 16.0 320 / 44 320 44 S DS 2.350 13.0 400 / 44 400 44 S DS 2.600 10.0 600 / 44 600 44 S DS 3.200 6.0 700 / 44 700 44 S DS 3.450 5.2 800 / 44 800 44 S DS 3.700 4.55 1000 / 44 1000 44 S DS 4.100 3.65 1100 / 44 1100 44 S DS 4.300 3.30 1800 / 44 1800 44 S DS 5.500 2.05 3 / 45 3 44 S SS 0.210 1600.0 4 / 45 4 45 S SS 0.240 1200.0 5 / 45 5 45 S SS 0.260 960.0 6 / 45 6 45 S SS 0.285 800.0 7 / 45 7 45 S SS 0.285 689.0 8 / 45 8 45 S SS 0.325 600.0 9 / 45 9 45 S SS 0.340 536.0 10 / 45 10 45 S SS 0.355 480.0 12 / 45 12 45 S SS 0.390 400.0 16 / 45 16 45 S SS 0.445 301.0 20 / 45 20 45 S SS 0.500 240.0 25 / 45 25 45 S SS 0.560 192.0 27 / 45 27 45 S SS 0.585 184.0 32 / 45 32 45 S SS 0.630 150.0 36 / 45 36 45 S DS 0.690 138.0 40 / 45 40 45 S DS 0.730 122.0 50 / 45 50 45 S DS 0.810 99.3 60 / 45 60 45 S DS 0.880 82.0 63 / 45 63 45 S DS 0.900 78.0 80 / 45 80 45 S DS 1.005 62.0 81 / 45 81 45 S DS 1.010 61.3 100 / 45 100 45 S DS 1.120 50.0 120 / 45 120 45 S DS 1.220 41.3 135 / 45 135 45 S DS 1.300 36.8 180 / 45 180 45 S DS 1.400 30.0 200 / 45 200 45 S DS 1.450 24.8 250 / 45 250 45 S DS 1.560 21.0 260 / 45 260 45 S DS 1.735 20.0 Product Catalogue Number SWG of Film Outer Nominal Maximum DC Construction of Wires Wires Coating Insulation OD (mm) Resistance Ω/Km 320 / 45 320 45 S DS 1.950 15.5 400 / 45 400 45 S DS 2.180 12.4 600 / 45 600 45 S DS 2.850 7.85 700 / 45 700 45 S DS 3.100 6.75 800 / 45 800 45 S DS 3.300 5.90 1000 / 45 1000 45 S DS 3.700 4.75 1100 / 45 1100 45 S DS 3.850 4.30 1800 / 45 1800 45 S DS 4.900 2.65 3 / 46 3 46 S SS 0.190 2050.0 4 / 46 4 46 S SS 0.215 1537.0 5 / 46 5 46 S SS 0.235 1230.0 6 / 46 6 46 S SS 0.255 1025.0 7 / 46 7 46 S SS 0.255 879.0 8 / 46 8 46 S SS 0.290 769.0 9 / 46 9 46 S SS 0.295 683.0 10 / 46 10 46 S SS 0.320 615.0 12 / 46 12 46 S SS 0.350 512.0 16 / 46 16 46 S SS 0.400 384.0 20 / 46 20 46 S SS 0.450 307.0 25 / 46 25 46 S SS 0.505 246.0 27 / 46 27 46 S SS 0.525 235.0 32 / 46 32 46 S SS 0.565 198.0 36 / 46 36 46 S DS 0.600 176.0 40 / 46 40 46 S DS 0.630 158.0 50 / 46 50 46 S DS 0.725 127.0 60 / 46 60 46 S DS 0.785 106.0 63 / 46 63 46 S DS 0.805 101.0 80 / 46 80 46 S DS 0.900 79.2 81 / 46 81 46 S DS 0.905 78.2 100 / 46 100 46 S DS 1.000 63.3 120 / 46 120 46 S DS 1.095 52.8 135 / 46 135 46 S DS 1.155 46.9 160 / 46 160 46 S DS 1.255 39.6 200 / 46 200 46 S DS 1.395 31.7 250 / 46 250 46 S DS 1.550 25.3 320 / 46 320 46 S DS 1.750 19.8 400 / 46 400 46 S DS 1.940 15.8 420 / 46 420 46 S DS 2.100 15.2 660 / 46 660 46 S DS 2.600 9.75 1050 / 46 1050 46 S DS 3.250 6.15 1710 / 46 1710 46 S DS 4.100 3.85 2700 / 46 2700 46 S DS 5.150 2.5 4200 / 46 4200 46 S DS 6.400 1.6 3 / 47 3 47 S SS 0.160 3284.0 4 / 47 4 47 S SS 0.180 2463.0 5 / 47 5 47 S SS 0.195 1970.0 6 / 47 6 47 S SS 0.210 1642.0 7 / 47 7 47 S SS 0.210 1407.0 Product Catalogue Number SWG of Film Outer Nominal Maximum DC Construction of Wires Wires Coating Insulation OD (mm) Resistance Ω/Km 8 / 47 8 47 S SS 0.240 1232.0 9 / 47 9 47 S SS 0.250 1095.0 10 / 47 10 47 S SS 0.260 985.0 12 / 47 12 47 S SS 0.285 821.0 16 / 47 16 47 S SS 0.325 616.0 20 / 47 20 47 S SS 0.360 493.0 25 / 47 25 47 S SS 0.405 394.0 27 / 47 27 47 S SS 0.420 376.0 32 / 47 32 47 S SS 0.455 317.0 36 / 47 36 47 S SS 0.480 282.0 40 / 47 40 47 S SS 0.505 254.0 50 / 47 50 47 S SS 0.560 203.0 60 / 47 60 47 S SS 0.615 169.0 63 / 47 63 47 S SS 0.625 161.0 80 / 47 80 47 S DS 0.725 127.0 81 / 47 81 47 S DS 0.730 125.0 100 / 47 100 47 S DS 0.805 101.0 120 / 47 120 47 S DS 0.875 84.6 135 / 47 135 47 S DS 0.925 75.2 160 / 47 160 47 S DS 1.005 63.4 200 / 47 200 47 S DS 1.120 50.7 250 / 47 250 47 S DS 1.245 40.6 320 / 47 320 47 S DS 1.400 31.7 400 / 47 400 47 S DS 1.560 25.4 650 / 47 650 47 S DS 2.150 14.5 1050 / 47 1050 47 S DS 2.700 9.0 1650 / 47 1650 47 S DS 3.350 5.7 2625 / 47 2625 47 S DS 4.150 3.6 4200 / 47 4200 47 S DS 5.250 2.25

Abbreviations: S = single-film coating SS = single serving DS = double serving

Parashar Vidyut Udyog D-183, Sector-10, Noida Uttar Pradesh, Pin-201301, India Phone : +91-120-6524601, Mob : +91-8285297730 Email : [email protected] Web : www.parasharvidyutudyog.com