earth_america
user_standard Connexion
action_search_stroke
earth_america
Log on to rate and give feedback 1 2 3 4 5 Log on to rate
0
Concept

Concept


Produits : AS-B, AS-P
Fonctionnalités : Matériel
Version produit : 3.2, 3.3, 2022, 2023, 2024
20/07/2021

Cable Selection

This is one of the most important selections having significant impact on the performance and reliability of the RS-485 network being installed. An incorrect cable selection can be difficult and expensive to reverse. The decision should not be made on previous examples of seeing some alternate non-compliant cable work.

With RS-485, two conductors are used to pass the differential data (A+ and B- signals) from one node to the next. To maintain the balanced characteristics between the two wires, the cable must provide twisted pairs and be specified for data communications. As the twisted pair passes along side other cables and equipment in the facility, there are a multitude of noise sources, radiated EMI and electromagnetic fields that will impose noise on to the twisted pair cable.

The shield does not provide any form of total protection. The shield inhibits a significant portion of high frequency radiated noise, but other fields may simply pass through. As long as the twisted pair of wires remains balanced, the noise will be imposed on the two wires equally. An imbalance of impedance to ground of the differential pair determines in part the susceptibility of the network to interference, regardless of it being inductive or capacitive coupled. When balanced, a noise appearing equally on both wires is called common mode noise. The RS-485 receiver only looks at the differential voltage seen between the two conductors and ignores the common mode noise. This is true up to the common mode voltage limits of the transceiver, which should be a minimum range of -7 V to +12 V. A reduction in this range, such as from fully exhausting transmitter CMV support with excess unit load, can make the bus susceptible to induced common mode noise.

The balanced performance of the cable requires more than just the twisted pair characteristics, although it is definitely the most important. The twisted pair cable can become unbalanced when encountering discontinuities in the capacitance between the two wires, or the capacitance from conductor to shield, or the impedance of the wires. This makes it important to select quality cable specified for RS-485 data communications. The cable supplier must provide cable specification that includes all of the characteristics seen in the table below. The recommended specification for these characteristics is also listed. These will provide the best results. You should avoid a cable where the manufacturer/supplier cannot provide the full cable specifications.

Table : Recommended Cable Characteristics

Characteristics

Recommendations

Type

Shielded Twisted Pair Low Capacitance

Twisted Wire Size

22 AWG to 24 AWG (0.33 mm² to 0.20 mm²)

Impedance

120 ohm

Capacitance (wire to shield)

<82 pF/m (<25 pF/ft)

Capacitance (wire to wire)

<46 pF/m (<14 pF/ft)

Maximum Length

1200 m (4000 ft) depending on termination and bias restrictions

Table : Recommended Twisted Pair Cables

Cable

Size

Pairs

Imp.

Cap1 a

Cap2 b

Vel

Plenum Rated

Belden 3105A

22 AWG Str (0.33 mm²)

1

120 ohm

36.1 pF/m (11 pF/ft)

68.6 pF/m (20.9 pF/ft)

78%

Belden 3107A

22 AWG Str (0.33 mm²)

2

120 ohm

36.1 pF/m (11 pF/ft)

68.6 pF/m (20.9 pF/ft)

78%

Belden 9841

24 AWG Str (0.20 mm²)

1

120 ohm

42.0 pF/m (12.8 pF/ft)

75.5 pF/m (23 pF/ft)

66%

Belden 9842

24 AWG Str (0.20 mm²)

2

120 ohm

42.0 pF/m (12.8 pF/ft)

75.5 pF/m (23 pF/ft)

66%

Belden 82841

24 AWG Str (0.20 mm²)

1

120 ohm

39.4 pF/m (12 pF/ft)

72.2 pF/m (22 pF/ft)

76%

Y

Belden 82842

24 AWG Str (0.20 mm²)

2

120 ohm

39.4 pF/m (12 pF/ft)

72.2 pF/m (22 pF/ft)

76%

Y

Belden 89841

24 AWG Str (0.20 mm²)

1

120 ohm

39.4 pF/m (12 pF/ft)

72.2 pF/m (22 pF/ft)

76%

Y

Belden 89842

24 AWG Str (0.20 mm²)

2

120 ohm

39.4 pF/m (12 pF/ft)

72.2 pF/m (22 pF/ft)

76%

Y

Alpha Wire 6453

22 AWG Str (0.33 mm²)

1

120 ohm

36.0 pF/m (11 pF/ft)

68.6 pF/m (20.9 pF/ft)

78%

Alpha Wire 6455

22 AWG Str (0.33 mm²)

2

120 ohm

36.0 pF/m (11 pF/ft)

68.6 pF/m (20.9 pF/ft)

78%

Alpha Wire 6412

24 AWG Str (0.20 mm²)

1

120 ohm

42.0 pF/m (12.8 pF/ft)

75.5 pF/m (23 pF/ft)

Alpha Wire 6413

24 AWG Str (0.20 mm²)

2

120 ohm

42.0 pF/m (12.8 pF/ft)

75.5 pF/m (23 pF/ft)

General Cable C0841A

24 AWG Str (0.20 mm²)

1

120 ohm

46.6 pF/m (14.2 pF/ft)

84.0 pF/m (25.6 pF/ft)

66%

General Cable C0842A

24 AWG Str (0.20 mm²)

2

120 ohm

37.4 pF/m (11.4 pF/ft)

67.3 pF/m (20.5 pF/ft)

66%

Connect-Air W241P2050FRIB

24 AWG Str (0.20 mm²)

1

120 ohm

35.8 pF/m (10.9 pF/ft)

64.3 pF/m (19.6 pF/ft)

78%

Y

Connect-Air W221P2010FRIB

22 AWG Str (0.33 mm²)

1

120 ohm

35.8 pF/m (10.9 pF/ft)

64.3 pF/m (19.6 pF/ft)

78%

Y

  1. Cap1 = Capacitance between the two conductors of the pair(s)
  2. Cap2 = Capacitance from each signal conductor to shield
  • RS-485 Communications
  • Generic RS-485 Network Devices
  • b3 BACnet Devices
  • MNB BACnet Devices
  • Viconics VT/VZ/SE 7xxx Series Devices