Multiple Conductor Cables

Part Number	Description / PDF	Quantity
30-01162 Tensility International Corporation	CBL 7CON 32AWG SHLD BLK BIO 153M	5
30-00495 Tensility International Corporation	CBL 3CON 28AWG SHLD BLK 1M BIO	39
30-01327 Tensility International Corporation	CBL 9CON 20AWG 153M GRY	0
31-00033 Tensility International Corporation	CBL COIL SHLD 3C 28AWG 1115MM	97
30-01134 Tensility International Corporation	CBL 5CON 32AWG SHLD GRY BIO 153M	0
30-00389 Tensility International Corporation	CABLE 4COND 24AWG BLACK 305M	10
30-01341 Tensility International Corporation	CBL 10CON 22AWG 153M WHT	0
30-00791 Tensility International Corporation	CABLE 2COND 16AWG WHITE 153M	0
30-01099 Tensility International Corporation	CBL 10CON 20AWG SHLD BLK 153M	0
30-01192 Tensility International Corporation	CBL 9CON 32AWG SHLD BLK BIO 153M	7
30-00419 Tensility International Corporation	CBL 2COND 26AWG BLACK/RED 305M	13
30-01002 Tensility International Corporation	CBL 2CON 18AWG SHLD WHT 153M	0
30-01151 Tensility International Corporation	CBL 7CON 24AWG SHLD WHT BIO 153M	0
31-00091 Tensility International Corporation	CBL COIL SHLD 7C 18AWG 2230MM	0
30-01488 Tensility International Corporation	CBL 7COND 24AWG SHLD 153M MPPE	6
30-00003 Tensility International Corporation	CABLE 2COND 24AWG BLACK 305M	24
30-01179 Tensility International Corporation	CBL 8CON 32AWG SHLD GRY BIO 153M	0
30-01295 Tensility International Corporation	CBL 6CON 26AWG 153M BLK	14
30-00802 Tensility International Corporation	CBL 2CON 300V 24AWG BLK 153M	10
30-01252 Tensility International Corporation	CABLE LSZH 2CON 20AWG 153M	12

Multiple Conductor Cables

1. Overview

Multiple Conductor Cables (MCC) are composite cable structures containing two or more individually insulated conductors enclosed within a common jacket. These cables enable simultaneous transmission of power, data, and control signals in complex systems. Their modular design optimizes space utilization while maintaining signal integrity, making them essential in industrial automation, telecommunications, and energy distribution systems.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Control Cables	Low capacitance, high flexibility, 300-1000V rating	PLC systems, factory automation
Power Cables	Large cross-section conductors, thermal-resistant insulation	Machinery power supply, HVAC systems
Data Communication Cables	Twisted pair configurations, 100 impedance	Ethernet networks, fieldbus systems
Signal Cables	Shielded designs, noise suppression	Sensor networks, instrumentation

3. Structure and Composition

Typical construction includes:

Conductors: Annealed copper or aluminum (solid/stranded), 0.14-10mm cross-section
Insulation: PVC, XLPE, or FEP materials with 300% elongation
Shielding: Aluminum-polyester foil (100% coverage) or braided copper (85% coverage)
Jacket: Flame-retardant PVC or LSZH compounds (0.8-3.0mm thickness)

Layered design prevents crosstalk between conductors while maintaining mechanical durability (20N/mm tensile strength).

4. Key Technical Parameters

Parameter	Typical Range	Significance
Conductor Count	2-104 conductors	Determines system integration density
Voltage Rating	300V-2000V	Defines operational safety margin
Temperature Range	-40 C to +125 C	Environmental adaptability
Shielding Effectiveness	60-100dB	EMI protection level
Bending Radius	7.5 OD to 15 OD	Installation flexibility

5. Application Areas

Primary industries utilizing MCC:

Industrial Automation: Robotic arms, CNC machines
Transportation: Rail vehicle control systems
Energy: Wind turbine pitch control systems
Telecommunications: 5G base station interconnects

Case Study: Automotive production lines use 24-conductor control cables to synchronize robotic welding stations with <0.1ms latency.

6. Leading Manufacturers

Manufacturer	Key Products	Specialization
Legrand	Okonite Multi-Conductor	Building automation solutions
Belden	8760 DataTuff	Industrial Ethernet cables
Prysmian Group	Fire resistant Ecos Z	Energy sector applications
Alpha Wire	3279 UltraFlex	High-flex robotics cables

7. Selection Guidelines

Key considerations:

Current carrying capacity vs. conductor size (I = 3.2 Amm for Cu)
Chemical resistance requirements (oil/grease exposure)
Signal transmission requirements (CAT5e/CAT6 data rate support)
Regulatory compliance (UL/CSA/IEC standards)
Mechanical stress factors (vibration, bending cycles)

Recommend conducting thermal cycling tests (-20 C to +85 C) for critical applications.

8. Industry Trends

Emerging developments include:

Hybrid cables integrating fiber optics and power conductors
Nano-coated conductors for 50% weight reduction
Smart cables with embedded temperature/sensor monitoring
Halogen-free materials meeting IEC 60754-1 standards
Miniaturization trend: 0.08mm micro-conductors in medical cables

Market forecasts indicate 6.2% CAGR through 2030 driven by Industry 4.0 adoption.