Stainless Steel Conductive Fabrics -
May. 20, 2024
Stainless Steel Conductive Fabrics -
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The company is renowned as the world's top-notch china silver coating conductive fabric factory. We are your comprehensive source for all requirements. Our highly skilled staff will assist you in locating the product you need.
Detailed Product Insights
Composition and Properties
- Fabric makeup: 40% polyester, 30% cotton, 30% conductive thread
- Avg. attenuation: ≥35dB within 10MHz – 3GHz
- Fabric weight: 220±10 g/m²
Attributes and Advantages
- High Electrical Conductivity
- Available in 12 colors
- RF/EMI/EMF/LF Blocking capabilities
- Ideal for Earthing/Grounding applications
- Anti-static/ESD resistant
- Effective against Radiation/Radiowaves/Microwaves
- Effortless to cut and sew
Overview
Stainless steel conductive fabrics excel in grounding sheets and anti-static garments. They block RFID/RF, reduce EMF/EMI, and provide Radiation/HF Signal/WiFi protection. These fabrics maintain the operational integrity of devices during EMP or CME events. Available in 12 colors including gray, light gray, grape purple, purple, light purple, dark blue, light cyan, blue, light blue, red, pink, and staple rayon gray.
Safety Information & Documentation
Safety: The fabric is non-toxic, tasteless, and odorless, making waste disposal as straightforward as regular trash.
Specifications
Stainless Steel Conductive Fabric
CF-SS-008-01
ItemUnitSpecification
Test StandardWidthmm1500GB/T4667-1995Weightg/m2220±10GB/T4669-1995Shielding EffectivenessdB35, 10MHz-3GHzPolyester%40Cotton%30Conductive thread%30
Available Colors: Gray, light gray, grape purple, purple, light purple, dark blue, light cyan, blue, light blue, red, pink, staple rayon gray. Please specify the color during checkout in Order Notes.
Available Sizes: Width 59.06″ inch (150 cm) x length 39.37″ inch (100 cm), 59.06″ (150 cm) x 59.06″ (150 cm), 59.06″ (150 cm) x 78.74″ (200 cm), and 59.06″ (150 cm) x 157.48″ (400 cm). For custom lengths, contact Nano3D Systems.
Extra Information
Ideal uses include grounding sheets, bags, curtains, tents, covers, anti-static apparel, and e-textiles. Also suitable for wallet or handbag inserts to protect credit cards from data theft. Efficient for shielding rooms & booths, car security key fob bags, and against cell towers, wireless routers, microwave signals, smart meters, security systems, radars, etc. It provides EMI/EMF blocking and EMP protection for electronics, blocking RF signals like cell phones, Bluetooth, WiFi, GPS, and more.
Customer Reviews
Cheryl B.
Last order was fantastic. I love this fabric for grounding sheets. Absolutely the best I've used in the past 8 years. Thank you!
★ ★ ★ ★ ★
Claudine S.
The fabric arrived swiftly and in perfect condition. I'm so pleased. Excellent customer service. I’ll be back with more orders. I’m using it for earthing sheets. Thanks again!
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★ ★ ★ ★ ★
Kent B.
I ordered stainless steel conductive fabrics to make a grounding sheet. Initially hesitant due to poor quality from past orders on other platforms, I was pleased with the high conductivity and quality of fabrics from Nano3D Systems. Excellent customer service, too. Thanks for offering great and reasonably priced products.
★ ★ ★ ★ ★
How to Effectively Utilize Conductive Fabric
Understanding Ohms Per Square
Conductive fabrics incorporate fibers like nylon and cotton combined with conductive metals such as stainless steel, silver, or copper. The resistance of a fabric is defined by the conductor type and construction method, usually indicated as Ohm/Sq or Ω /▢. This metric is used to describe the sheet resistance of the material.
Interpreting the Value
If marked as 2 Ω per ▢, a cut square will measure 2 Ohms regardless of size. For different shapes, the resistance is calculated by multiplying the aspect ratio with the Ohms per square value. For instance:
A 1" x 3" rectangle has an aspect ratio of 3, yielding a resistance of:
2 Ω (per ▢) x 3 (aspect ratio) = 6 Ohms
The measurement takes thickness into account, requiring two multimeters and 4 probes for precise calculation. For practical purposes, use a single multimeter for your project needs.
Determining Resistance
Knowing the Ohm/Sq value guides material selection. Measure resistance using a multimeter on your specific shapes and keep these values handy. For example, if a swirl cut measures 6 Ω, a circuit with 10 swirls will approximate 60 Ω.
Voltage and Current Guidelines
Conductive fabric vendors often do not list current or voltage ratings. When absent, contact the manufacturer. Uninsulated circuits can be hazardous; avoid shorts to prevent electrocution. Insulate and protect your circuits as necessary.
Conductive Versus Resistive
Electrical conductivity measures a fabric's current-carrying ability (low resistance equals high conductivity). Materials are termed resistive when exhibiting higher resistance, typically over 1K Ω/▢. Always verify resistance yourself using a multimeter.
Selecting Material for Specific Uses
For circuit traces and contact switches, opt for fabrics with low resistance. Capacitive touch switches can use higher resistance fabrics. For resistors, cut resistive materials to desired resistance values. Piezoresistive materials change resistance with pressure, making them ideal for sensors like force and stretch sensors.
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