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Download A Guide to Specifying Encapsulated Transformers
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A Guide to Specifying Encapsulated Transformers for use in Power Supplies Spencer Manley – Applications Engineer, Transonics plc. What is a transformer? A transformer is an electromechanical device that takes an Alternating Voltage (AC) and transforms it to another alternating voltage via an isolated magnetic flux path. A transformer has 2 basic functions. 1) To convert one AC voltage to another, either greater than, equal to or less than the AC voltage applied. 2) To provide an isolation barrier for safety purposes Transformer types are often referred to as:Step up transformer The input voltage is increased at the output to generate a higher voltage. This is typically used for distributing power over a longer distance as the output copper wires will have to carry less current, reducing losses dissipated as heat. Step down transformer The input voltage is decreased at the output to generate a lower voltage. This is usually used for power supplies to provide a safe and lower voltage to power low voltage electronics. Isolation transformer The input and output have the same voltages and the transformer construction provides a safety barrier. This would be used if there was a safety requirement to prevent the end user creating a path to ground for current to flow in the event of an electrical breakdown. This article will consider the essential specification requirements of a transformer for use in electronic power supplies, the “step-down” transformer design mentioned above Virtually every product in common use requires a power supply to convert mains voltages to those required for the end product. In most cases this will be an AC input power source which could be converted to a higher DC voltage for a switched mode power supply or reduced to create a low DC voltage for a simple linear power supply. Common power supply output requirements are in the range 5-24V or 48V for telecoms equipment As the majority of equipment is supplied from the 230VAC mains a 50-60 Hz operating frequency will be the most common design The following diagram shows a basic 50-60Hz power supply diagram. The step down transformer is highlighted in Yellow For any power supply design the requirements of the load will have to be known Some of the load requirements may not be obvious at the outset and not be known until prototype testing shows there are more parameters to be considered for the final design. Basic considerations for a power supply transformer; The power consumed by the transformer is not equal to the power being drawn from its output, there will be internal losses. Power in = Power out + Losses These losses can be very significant. A transformer functions by winding an input “primary” coil, electromagnetically connected to a secondary “output” coil using a “Turns Ratio” to achieve the output required relative to the input voltage. The voltage [Vp] applied to the primary divided by the Voltage [Vs] on the secondary will determine the turns ratio. Therefore Vp/Vs = Np/Ns (N being Turns) = Turns Ratio The output voltage is calculated using Vs=Vp x Np/Ns For correct operation of the end power supply output Voltage, output current, line regulation, load regulation, short circuit protection, thermal performance and efficiency all need to be considered Output Voltage (the output voltage generated by the transformer turns ratio) Design considerations: Is the design a basic single voltage output? Will more than one output be required? Would multiple outputs need to be isolated from each other or would a common-rail design be satisfactory? Does the output require opposing voltages? E.G. +/- 12V Output Current (the current required to power the load circuit) The load requirements and ambient conditions of the load circuit will determine the size and rating of the transformer design. Will the power level be constant or will it be nominally a low output current level with high output peak currents as in a battery charging circuit or data communications system? A design appearing to require 1VA may only require that capacity for short bursts of time allowing size and cost saving by de-rating to possibly a 0.6VA transformer design provided the duration of the increased current spikes doesn’t saturate the core. Line Regulation (variation in the output voltage in response to a change in the input voltage) A transformer is basically a potential divider that will convert the AC input voltage up or down depending upon the ratio of the turns specified. If a design is based around a nominal 230V input care must be taken to ensure that the output voltage swing is catered for. A 230V input and a 12V output gives an approximate ratio of 19:1 Clearly the input voltage can vary depending upon how clean the mains supply is and the other load conditions on the local power feed. For example, the input voltage may drop to 210V having the effect of reducing the output voltage to 11V or should the input rise to 250V the output will rise to 13V. This line fluctuation will need to be considered if it will affect the intended load. Load regulation (variation in output voltage in response to a change in the load current) Load regulation of a transformer is determined by measuring the voltage at the output with no load applied and then measured again once the full load is connected. A typical power supply specification may ask for 12V on load but could reach in excess of 20V off load. This can vary depending on the internal construction of the transformer and must be taken into consideration in the design. Components specified in a power supply will have a maximum voltage rating which must be within the maximum off load voltage specification. Short Circuit Proof (a fault condition created by a failure at the output of the transformer) An encapsulated transformer could pose a fire hazard if the design is subjected to a direct short circuit under a fault condition. With encapsulated designs the short circuit current is limited by the resistance of the windings, which together with the encapsulating materials used, should keep the temperature within safety requirements and remove the possibility of a fire. Isolation (the minimum breakdown voltage that can be applied between the input and output) All transformers inherently provide isolation between input and output windings. This is achieved by either designing the windings on 2 separate parts of the coil former or by putting a barrier media (tape or plastic housings) between the windings internally. Any barrier will eventually break down given a high enough voltage applied between input and output allowing a high voltage a path from one side to the other. Most specifications call for protection to around 1500V minimum. Efiter encapsulated transformers, supplied by Transonics, have an innovative internal design and encapsulation technique and can offer 5000V for 1 minute. Thermal Considerations Heat is generated inside a transformer in 2 ways, Conducted and Radiated. Conducted heat is generated from the primary resistance of the windings. Current passing through these windings will generate heat within the conducted element which is known as Copper Loss. Heat generated from radiated loss is caused by the energy moving via the magnetic path from the Primary to the Secondary inside the transformer, not from a physical resistance path. The energy passing through the magnetic core material will be conducted as Flux and radiated as Heat. This is referred to as “Core Losses”. Low cost, low quality core materials produce more losses and consequently raise the internal temperature of the transformer. Use of a laminated core with multiple sheets of iron instead of a solid core will lower the thermal skin effect and therefore lower the internal temperature but will add cost in manufacture. Transformers can be deigned with very low loss cores offering higher efficiency but this may not always be the most economical solution. Thermal considerations and the relative cost of core designs needs to be a design consideration from the outset. Efficiency The efficiency of a transformer is a function of the quality of the Copper wire used for the windings and the material and design of the Cores used including with any gaps in the core construction. The ideal is clearly 100% efficiency as this offers a perfect conduction path but there will always be resistances and other losses in the transformer circuit. Most common transformer designs running at 50Hz provide efficiency levels around 55-65% due to these losses. To specify transformers with greater efficiency better cores which operate at higher frequencies will be required. For very high efficiencies changing the power supply topology to a switch-mode design may be desirable. Working with a trustworthy supplier From the above it can be seen that many technical and safety critical factors are involved in the design of a transformer making it a specialised task which most product designers outsource to a specialist supplier. While standard transformers may still be widely used, custom designs are very common and finding a reliable and responsive supplier is a key part of the supply chain. Transonics have a UK based design team and supply transformers from Efiter, a leading European based specialist transformer manufacturer. Efiter transformers are 20% lighter than most of their competitors as a result of using their own specially manufactured encapsulating resin and the use of high performance, high reliability wire and a very high precision winding process. High isolation voltages up to 5KV are available which greatly exceeds market norms and all Efiter transformers are 100% tested on and off load, at maximum load and are isolation tested. With transformer solutions from 0.35VA up to over 30VA, Transonics can support multiple configurations ranging from a single 115V or single 230V AC level to a dual 115V input and outputs in either a single isolated, dual isolated or a dual centre tapped configuration Efiter offers the most varied range of solutions in the market place today. For more information on Efiter transformers from Transonics visit www.transonics.com Transonics PLC Breakspears Park Breakspears Way Hemel Hempstead HP2 4UL Tel: 0845 567 8899 Email: [email protected] www.transonics.com PR/028