Inductive Power Transfer Solutions

Inductive Power Transfer Solutions for rail-guided material handling systems or amusement rides have a protruding primary track arrangement in which an E-Pickup envelops both track cables from multiple sides. The lack of mechanical contact between stationary and moving parts of an inductive power transfer solution results in a wide range of superior features:

...for Electrified Monorail Systems

High availability and safety
Large mechanical traverse tolerances
No exposed electrical contacts
High traveling speeds
Unlimited forward and reverse movement
Not susceptible to environmental influences
Low Maintenance and Operating Costs
No wearing mechanical parts
No collector dust generated
Easy to install
Brackets clip into the rail
Double cable primary

...for Skillet Systems and Slat Conveyors

High availability and safety
Large mechanical traverse tolerances
No exposed electrical contacts
Suitable for frequent engagement/disengagement
No arcing
Not susceptible to environmental influences
Low Maintenance and Operating Costs
No wearing mechanical parts
Easy to install
Brackets clip into the carrier
Double cable primary

When supplying power to rail-mounted vehicles, continuous inductive supply is generally required along the entire travel path. The inductive power transfer solutions primary track is installed parallel to the rail or along the travel path. The pick-ups and controllers are mounted on the vehicles. As with all continuous inductive power transfer solutions, transfers are made using the dual-cable model, i.e. with a forward and return cable.

Pickups and Regulators are available in different power levels and output voltages to match the applications being served. If a single pickup and regulator combination is not sufficient to provide the required power level, they can be combined to provide higher power levels together. Graded power supply is provided within the design of the regulators.

The most common output voltage is 560 V DC. 560 V DC is the DC equivalent of a 400 V AC supply. Typically, inductive power transfer systems supply power to variable speed drives or mobile controllers with integrated variable speed drives. Standard frequency inverters have an input rectifier that converts the normally supplied AC supply voltage to DC, and the variable frequencies to control drives are then applied in a second stage. Since it does not make technical sense to design inductive power transfer solutions that provide AC outputs that are immediately rectified back to DC, regulators provide DC outputs that are fed either into the phase inputs or, if necessary, directly into the DC bus of the drive.

The pickup and regulator output voltages are tailored for specific applications. E-Shape Pickups are standard for rail-guided systems, offering high power density and optimized EMC characteristics. Their design focuses the field centrally, reducing spread and enhancing efficiency. The absence of AC outputs simplifies power electronics, reducing complexity, volume, cost, and losses, resulting in economic and ecological benefits.

Specification

Power Supplies:
Up to 40 kW nominal power and higher peak power

Loop/Track Lengths:
From few meters to some hundred meters with a single Power Supply. Hundreds of meters, going into the thousands potentially i.e., with huge EMS installation applying multiple Power Supplies.

Vehicle Side Power Levels provided:
Flat Pickups come typically with integrated power electronics to minimize installation efforts on the vehicle side by eliminating extra wiring, plugs, etc. E-Pickups come typically with separate power electronic units (Regulators).
Flat Pickups go up to 2,5 kW and have mostly 560 V DC outputs supplying the DC-buses in Inverters typically applied in automated systems to drive motors.
E-Pickups go up to 4 kW, Regulators do match power wise and come mostly also with 560 V DC outputs, dedicated solutions may come with different voltages, i.e. 48 V DC.

Higher power requests can be served by the implementation of 2 or more Pickups respectively Pickup and Regulator combinations.

Downloads

Product Overview Inductive Power Transfer

PDF | 2.09 MB

Language: English

Document type: Brochures

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Inspection of Inductive Power Transfer Systems

PDF | 1.15 MB

Language: English

Document type: Brochures

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IBC9100-0001-EN Inductive Power Transfer System 9100

PDF | 165.61 KB

Language: English

Document type: Commissioning Checklists

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FAQ

Why does Conductix-Wampfler use special cables?

The cables used are called Litz cables. Due to the skin effect, currents at 20 kHz flow only in the outer surface of a conductor and not through its entire cross-section. This means that a standard cable must be significantly de-rated or operate with very high losses. Conductix-Wampfler has developed special stranded cables for inductive power transfer solutions. These consist of many individually insulated strands, each with a diameter smaller than the skin depth. This structure creates a cable with a very large total surface area, so that virtually the entire cross section carries current.

What is the purpose of capacitor boxes?

Inductive power transfer solutions resonate both the primary and secondary circuits. Power transfer is most effective when the primary and secondary circuits resonate at the same frequency. The secondaries are independently tuned systems. Environment and track length have a variable influence on the primary side. Depending on the track inductance L, additional capacitance C may be required to achieve resonance. There is also a voltage drop along the track. This is compensated by the track capacitors. Capacitor boxes are placed at regular intervals along the track so that the voltage drop at any point does not exceed the specified values.