Cables and busways: Difference between revisions
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Two types of distribution are possible:
- By insulated wires and cables
- By busbar trunking (busways)
Distribution by insulated conductors and cables
Definitions
- Conductor
A conductor comprises a single metallic core with or without an insulating envelope.
- Cable
A cable is made up of a number of conductors, electrically separated, but joined mechanically, generally enclosed in a protective flexible sheath.
- Cableway
The term cableway refers to conductors and/or cables together with the means of support and protection, etc. for example : cable trays, ladders, ducts, trenches, and so on… are all “cableways”.
Conductor marking
Conductor identification must always respect the following three rules:
- Rule 1
The double colour green and yellow is strictly reserved for the PE and PEN protection conductors.
- Rule 2
- When a circuit comprises a neutral conductor, it must be light blue or marked “1” for cables with more than five conductors
- When a circuit does not have a neutral conductor, the light blue conductor may be used as a phase conductor if it is part of a cable
with more than one conductor
- Rule 3
Phase conductors may be any colour except:
- Green and yellow
- Green
- Yellow
- Light blue (see rule 2)
Conductors in a cable are identified either by their colour or by numbers (see Fig. E34).
Number of conductors in circuit | Circuit | Fixed cableways | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Insulated conductors | Rigid and flexible multi-conductor cables | ||||||||||||
Ph | Ph | Pn | N | PE | Ph | Ph | Ph | N | PE | ||||
1 | Protection or earth | G/Y | |||||||||||
2 | Single-phase between phases | R3 | R3 | BL | LB | ||||||||
Single-phase between phase and neutral | R3 | LB | BL | LB | |||||||||
Single-phase between phase and neutral + protection conductor | R3 | G/Y | BL | G/Y | |||||||||
3 | Three-phase without neutral | R3 | R3 | R3 | BL | B | LB | ||||||
2 phases + neutral | R3 | R3 | LB | BL | B | LB | |||||||
2 phases + protection conductor | R3 | R3 | G/Y | BL | LB | G/Y | |||||||
Single-phase between phase and neutral + protection conductor | R3 | LB | G/Y | BL | LB | G/Y | |||||||
4 | Three-phase with neutral | R3 | R3 | R3 | LB | BL | B | BL | LB | ||||
Three-phase with neutral + protection conductor | R3 | R3 | R3 | G/Y | BL | B | LB | G/Y | |||||
2 phases + neutral + protection conductor | R3 | R3 | LB | G/Y | BL | B | LB | G/Y | |||||
Three-phase with PEN conductor | R3 | R3 | R3 | G/Y | BL | B | LB | G/Y | |||||
5 | Three-phase + neutral + protection conductor | R3 | R3 | R3 | LB | G/Y | BL | B | BL | LB | G/Y | ||
> 5 | Protection conductor: G/Y - Other conductors: BL: with numbering The number "1" is reserved for the neutral conductor if it exists |
G/Y: Green and yellow BL: Black R3: As indicated in rule 3 LB: Light blue B: Brown
Fig. E34: Conductor identification according to the type of circuit
Note: If the circuit includes a protection conductor and if the available cable does not have a green and yellow conductor, the protection conductor may be:
- A separate green and yellow conductor
- The blue conductor if the circuit does not have a neutral conductor
- A black conductor if the circuit has a neutral conductor
In the last two cases, the conductor used must be marked by green and yellow bands or markings at the ends and on all visible lengths of the conductor.
Equipment power cords are marked similar to multi-conductor cables (see Fig. E35).
Fig. E35: Conductor identification on a circuit-breaker with a phase and a neutral
Distribution and installation methods (see Fig. E36)
Distribution takes place via cableways that carry single insulated conductors or cables and include a fixing system and mechanical protection.
Fig. E36: Radial distribution using cables in a hotel
Busbar trunking (busways)
Busways, also referred to as busbar trunking systems, stand out for their ease of installation, flexibility and number of possible connection points
Busbar trunking is intended to distribute power (from 20 A to 5000 A) and lighting (in this application, the busbar trunking may play a dual role of supplying electrical power and physically holding the lights).
Busbar trunking system components
A busbar trunking system comprises a set of conductors protected by an enclosure (see Fig. E37).
Used for the transmission and distribution of electrical power, busbar trunking systems have all the necessary features for fitting: connectors, straights, angles, fixings, etc. The tap-off points placed at regular intervals make power available at every point in the installation.
Fig. E37: Busbar trunking system design for distribution of currents from 25 to 4000A.
The various types of busbar trunking:
Busbar trunking systems are present at every level in electrical distribution: from the link between the transformer and the low voltage switch switchboard (MLVS) to the distribution of power sockets and lighting to offices, or power distribution to workshops.
Fig. E38: Radial distribution using busways
We talk about a distributed network architecture.
There are essentially three categories of busways.
- Transformer to MLVS busbar trunking
Installation of the busway may be considered as permanent and will most likely never be modified. There are no tap-off points.
Frequently used for short runs, it is almost always used for ratings above 1,600 /2,000 A, i.e. when the use of parallel cables makes installation impossible. Busways are also used between the MLVS and downstream distribution switchboards.
The characteristics of main-distribution busways authorize operational currents from1,000 to 5,000 A and short-circuit withstands up to 150 kA.
- Sub-distribution busbar trunking with low or high tap-off densities
Downstream of main-distribution busbar trunking , two types of applications must be
supplied:
- Mid-sized premises (industrial workshops with injection presses and metalwork machines or large supermarkets with heavy loads).
The short-circuit and current levels can be fairly high (respectively 20 to 70 kA and 100 to 1,000 A)
- Small sites (workshops with machine-tools, textile factories with small machines,supermarkets with small loads). The short-circuit and
current levels are lower (respectively 10 to 40 kA and 40 to 400 A)
Sub-distribution using busbar trunking meets user needs in terms of:
- Modifications and upgrades given the high number of tap-off points
- Dependability and continuity of service because tap-off units can be connected under energized conditions in complete safety
The sub-distribution concept is also valid for vertical distribution in the form of 100 to
5,000 A risers in tall buildings.
- Lighting distribution busbar trunking
Lighting circuits can be distributed using two types of busbar trunking according to whether the lighting fixtures are suspended from the busbar trunking or not.
- busbar trunking designed for the suspension of lighting fixtures
These busways supply and support light fixtures (industrial reflectors, discharge lamps, etc.). They are used in industrial buildings, supermarkets, department stores and warehouses. The busbar trunkings are very rigid and are designed for one or two 25 A or 40 A circuits. They have tap-off outlets every 0.5 to 1 m.
- busbar trunking not designed for the suspension of lighting fixtures
Similar to prefabricated cable systems, these busways are used to supply all types of lighting fixtures secured to the building structure. They are used in commercial buildings (offices, shops, restaurants, hotels, etc.), especially in false ceilings. The busbar trunking is flexible and designed for one 20 A circuit. It has tap-off outlets every 1.2 m to 3 m.
Busbar trunking systems are suited to the requirements of a large number of buildings.
- Industrial buildings: garages, workshops, farm buildings, logistic centers, etc.
- Commercial areas: stores, shopping malls, supermarkets, hotels, etc.
- Tertiary buildings: offices, schools, hospitals, sports rooms, cruise liners, etc.
Standards
Busbar trunking systems must meet all rules stated in IEC 61439-6.
This defines the manufacturing arrangements to be complied with in the design of busbar trunking systems (e.g.: temperature rise characteristics, short-circuit withstand, mechanical strength, etc.) as well as test methods to check them.
The new standard IEC61439-6 describes in particular the design verifications and routine verifications required to ensure compliance.
By assembling the system components on the site according to the assembly instructions, the contractor benefits from conformity with the standard.
Note: within IEC 61439-x series, specific requirements for BTS will be moved to IEC 61439-6 (not published yet)
The advantages of busbar trunking systems
Flexibility
- Easy to change configuration (on-site modification to change production line configuration or extend production areas).
- Reusing components (components are kept intact): when an installation is subject to major modifications, the busbar trunking is easy to dismantle and reuse.
- Power availability throughout the installation (possibility of having a tap-off point every meter).
- Wide choice of tap-off units.
Simplicity
- Design can be carried out independently from the distribution and layout of current consumers.
- Performances are independent of implementation: the use of cables requires a lot of derating coefficients.
- Clear distribution layout
- Reduction of fitting time: the trunking system allows fitting times to be reduced by up to 50% compared with a traditional cable installation.
- Manufacturer’s guarantee.
- Controlled execution times: the trunking system concept guarantees that there are no unexpected surprises when fitting. The fitting time is clearly known in advance and a quick solution can be provided to any problems on site with this adaptable and scalable equipment.
- Easy to implement: modular components that are easy to handle, simple and quick to connect.
Dependability
- Reliability guaranteed by being factory-built
- Fool-proof units
- Sequential assembly of straight components and tap-off units making it impossible to make any mistakes
Continuity of service
- The large number of tap-off points makes it easy to supply power to any new current consumer. Connecting and disconnecting is quick and can be carried out in complete safety even when energized. These two operations (adding or modifying) take place without having to stop operations.
- Quick and easy fault location since current consumers are near to the line
- Maintenance is non existent or greatly reduced
Major contribution to sustainable development
- Busbar trunking systems allow circuits to be combined. Compared with a traditional cable distribution system, consumption of raw materials for insulators is divided by 4 due to the busbar trunking distributed network concept (see Fig. E39).
- Reusable device and all of its components are fully recyclable.
- Does not contain PVC and does not generate toxic gases or waste.
- Reduction of risks due to exposure to electromagnetic fields.
Fig. E39: Example of a set of 14 x 25A loads distributed along 34 meters (for busway, Canalis KS 250A)
New functional features for Canalis
Busbar trunking systems are getting even better. Among the new features we can mention:
- Increased performance with a IP55 protection index and new ratings of 160 A through to 1000 A (Ks).
- New lighting offers with pre-cabled lights and new light ducts.
- New fixing accessories. Quick fixing system, cable ducts, shared support with “VDI” (voice, data, images) circuits.
Busbar trunking systems are perfectly integrated with the environment:
- white color to enhance the working environment, naturally integrated in a range of electrical distribution products.
- conformity with European regulations on reducing hazardous materials (RoHS).
Examples of Canalis busbar trunking systems
Fig. E41: Rigid busbar trunking able to support light fittings : Canalis KBA or KBB (25 and 40 A)
Fig. E43: A busway for medium power distribution: Canalis KN (40 up to 160 A)
Fig. E44: A busway for medium power distribution: Canalis KS (100 up to 1000A)
Fig. E45: A busway for high power distribution: Canalis KT (800 up to 5000 A)