Power

Calling Constant Current

8th May 2013
ES Admin
0
In the vast world of power supply applications, we can identify two main categories for regulating the power applied to the load. The first being ‘constant voltage’, where the control loop maintains a constant voltage to varying load current demands and the second, ‘constant current’ where the current is maintained constant to vary the voltage applied to the load. By Giacomo Mazzullo, Business Development Manager for TDK-Lambda.
Since current flow is closely related to the flow of charge over time, having constant current control allows the user to accurately control the process and in certain circumstances reverse it.



In industrial applications, the currents involved are often very high and generally require the current to be precisely regulated and accurately varied or controlled. In this article we will focus on the following processes: water purification; metal purification; deposition, and; active corrosion control.



Water Purification



One of the most common methods for ultra-purification of water, even for industrial applications, is water Electrodeionisation using ion exchange resins in the form of thin membranes. After various stages of filtration that removes almost all the salts and minerals from the water, this method removes ions from the water to produce pure water with a high level of purity and very low conductivity.



For filtering, special ion exchange membranes are used that require an external power supply. Depending on the extent and degree of purification desired, this can require a DC power supply voltage up to 600V and currents of several tens of Amps. When applying a voltage between the anode and the cathode of the membrane, the ions dissolved in the water are extracted because they are attracted to, and forced to pass through, the anionic and cationic membranes. The degree of purification depends on the applied current level.



As the conductivity of the water is variable, the system needs to know the amount of charge applied to control the current flow and therefore the right level of purification to be achieved.





Figure 1: Ion exchange membrane



If the ion concentration of the water were to be too high (high conductivity), a power supply with constant voltage regulation could cause damage to the membranes because of the resulting high current that would flow. Constant current control prevents this from happening by regulating the current to appropriate levels. The use of constant current programmable power supplies allows a highly manageable and flexible control of the water purification process. The use of highly efficient power supplies allows further savings in operating costs.



Metal Purification



An industrial process widely used for the purification of metals (especially aluminium and copper) is electrolysis. The material to be purified is immersed in a ‘tub of electrolyte’, then a potential difference is applied between the sample to be purified (in Figure 2, copper acts as the anode) and the cathode is where the pure material is collected.





Figure 2: Schematic copper electrolysis



In this process, the amount of copper deposited or 'purified' is directly related to the applied current. The use of a constant current power supply allows the perfect control of the process.



These processes typically use currents in the order of thousands of Amps, low <5Vdc, operating voltages, and very high power. For example, 15MWh of electricity is needed to produce 1 ton of aluminium. The use of high-efficiency power supplies clearly creates significant savings in terms of energy bills and operating costs.



Deposition



Deposition is a process that is regularly used to coat a thin layer of precious materials (gold, chrome, titanium, etc.) onto a substrate that is ‘technically poor’ or with different mechanical characteristics; the primary reason for using thin layer coatings is to obtain a better surface property, which can range from improved hardness or resistance to corrosion, to a glossy or matt appearance.



One of the several different methods of deposition is ‘vacuum evaporation’. The basic principle consists of the material to be deposited being evaporated from a source, accelerated by an electric field applied appropriately, and then deposited onto the substrate.



Electron beam evaporation is a process that takes place in a vacuum chamber. The filament is heated by applying a DC voltage across its terminals and, when it has reached a suitable temperature, electron extraction is possible. Using an applied electric field, these electrons are accelerated from the filament to the crucible that holds the material to be evaporated. The beam is focused using the magnetic fields generated by the coils present close to the source and crucible.



Constant current power supplies are used to power the filament, magnets and focus circuitry (see Figure 3) in order to:



-ensure the temperature of the filament remains constant; any fluctuations may result in variation in the flow of electrons;



-focus the beam using Magnetic Flux (programming the current allows the user to vary the focus of the beam);



-maintain deflection of the magnetic flux (programming the current allows the user to vary the beam’s deflection).





Figure 3: Electron beam evaporation



The precise control of all these parameters, together with the use of high performance power supplies with low ripple and high dynamic response, allows the user to obtain a deposition of high quality and uniformity. A better, more reliable process minimises waste and increases product reliability.



Active Corrosion Control



Bridges, ships and offshore wind turbines are three examples where the prevention of corrosion of the structure is very important and greatly reduces operating costs.





Figure 4: Prevention of corrosion - sacrificial anode



For environmental reasons, the traditional passive ‘sacrificial anode’ method of corrosion control, as shown in Figure 4, is increasingly being replaced in favour of active prevention, which is implemented by applying an ‘impressed current’ (Figure 5).



In the passive method the anode (of a different metal to the structure) is ‘sacrificed’ in order to ensure that the structure is protected from corrosion. In the ‘active’ method, a sophisticated electronic current control system is used to inject a reverse current to that generated from corrosion to protect the structure.





Figure 5: Prevention of corrosion - impressed current



In the first case, it is easy to deduce the need to periodically replace the sacrificial anode (with consequent costs and dispersion of metals in the water), in the second case the only costs will be that of the system and the energy used.



High efficiency and the ability to control current and voltage across the broadest possible range are the main characteristics required for power supplies deployed in these applications.



TDK-Lambda, a leader in technological research in the field of power supplies, has developed several ‘Constant Current’ power supply solutions. The ZUP, Z + and Genesys programmable power supplies allow full control of the current and the output voltage, as well as feedback on the same parameters. In addition, the availability of isolated interfaces, analogue, digital RS232/485, IEEE488 and LAN allows a high flexibility of integration and system control. The power ratings range from 200W to 15KW with the possibility of placing up to 4 units in parallel, to increase the power up to 60KW and output currents up to 4000A.



In addition, TDK-Lambda has the capability to optimise a standard product or even develop a custom solution to meet the specific needs of a particular user application.

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