AC to DC Converter
Alternating current (AC) is used for power line transmission and for high power devices like appliances and lights. The characteristics of AC make it ideal for transmission over long lines and for delivering large amounts of power for relatively unregulated uses, such as generating heat and light. Lower power appliances and devices require the closely regulated control of direct current power (DC). As a normal house is supplied with AC, it must be converted to DC for many uses. Use these tips to learn how to make an AC to DC converter.
You can watch the video below to help to understand it more
Step 1 AC to DC Converter
Select a transformer. A transformer contains 2 magnetically coupled wire windings. One winding is called the primary. The primary is driven by the main AC supply. The other winding is called the secondary. The secondary serves as the power input from the AC to DC converter.
AC mains provide 120 volts AC. If 120 volts AC were directly converted to a DC voltage, the resulting DC voltage would be far too high a voltage for use by appliances and devices. The primary and secondary windings of the transformer are scaled to each other in order to produce a lower voltage on the secondary winding.
Choose a secondary winding. The AC output of the secondary winding should be rated as the same voltage of DC that is being created.
Step 2 AC to DC Converter
Wire the primary winding of the transformer to the main AC supply. This transformer connection has no polarity and may be connected either way.
Step 3 AC to DC Converter
Connect the secondary winding of the transformer to a full wave bridge rectifier package. The transformer connections and the connections to the marked inputs of the rectifier package have no polarity and may be connected either way.
Build a full wave rectifier.
`This rectifier can be built up from 4 discrete rectifying diodes, rather than using a rectifier bridge package. The diodes will be marked to show a positive (cathode) end and a negative (anode) end. Connect the 4 diodes into a loop. Connect the cathode of diode 1 to the cathode of diode 2. Connect the anode of diode 2 to the cathode of diode 3. Connect the anode of diode 3 to the anode of diode 4. Connect the cathode of diode 4 to the anode of diode 1.
Wire the discrete rectifier to the transformer secondary. The transformer secondary should be connected to the cathode of diode 3 and the cathode of diode 4. There is no required polarity for these connections. The positive output of the rectifier is at the point where the cathodes of diodes 1 and 2 join. The negative output of the rectifier is at the point where the anodes of diodes 3 and 4 join.
Step 4 AC to DC Converter
Attach a smoothing capacitor. Attach a polarized capacitor across the output connections of the rectifier. The positive terminal of the polarized capacitor must connect to the positive output of the regulator. This capacitor should be sized such that the capacitance in farads (F) is equal to (5 times the current to be supplied by the AC to DC converter) divided by (transformer secondary rating times 1.4 times frequency). Frequency varies from country to country, but is typically either 50 Hertz (Hz) or 60 Hertz.
Step 5 AC to DC Converter
Provide the final regulation. Choose a commercially available voltage regulator designed to control the output of the AC to DC converter to the desired output voltage. The regulator will be a 3-pin device. The regulator pins will be a common, an input from the smoothing capacitor and an output of the regulator. This regulator output also will be the final output of the completed AC to DC converter.
Wire the regulator as directed in the manufacturer’s data sheet. There probably will be a noise suppression capacitor specified in the regulator manufacturer’s data sheet. Acquire and install that capacitor per the manufacturer’s data sheet for the regulator.
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