Showing posts with label REGULATOR. Show all posts
Showing posts with label REGULATOR. Show all posts

How Regulator with 2 Photocoupler

Posted by Unknown at 1:00 AM Thursday, November 20, 2014 Labels: , , , , 0 comments
Working of Regulator with 2 Photocoupler that is :
  • Photocoupler N901 - used as a coupling-off control on the regulator by mikrokontrol. Which is set high and low voltage B + (st-by at the B + voltage is low). Control of the pin-37 POWER mikrokontrol → V610 → VD913 V908 → N901.
  • Photocoupler N903 - used to control on-off the regulator of X-ray circuit protector. X-ray protector circuit of flyback → VD451 → VD452 → SCR VS472. If the flyback voltage regulator over the job will automatically be turned off by N903
  • To disable the X-ray circuit protector, it can be temporarily removed photocoupler N903 first. In normal conditions the voltage at the transistor V474 should be zero.

Regulator Schematics
Trobelshuting there is no voltage for 5v st-by on the secondary :

  1. Disable by removing the first circuit protectors N903
  2. Check the voltage of 300V
  3. Check all transistors
  4. Check the start voltage of 300V by R909 >> R906 to the base of transistor power regulator
  5. Check the feedback C910 >> R904 (to oscillate)
Continue reading[...]

12 Volt 20 Ampere Regulator circuit with explanation

Posted by Unknown at 8:30 PM Tuesday, November 11, 2014 Labels: , , , , , , , 0 comments

A heavy duty 13.8V power supply is a fine thing to have in the shack, but unless you acquire one secondhand, is an expensive little beastie to buy. This means building one should be considered, not only for the cost savings, but also because you can brag about it on air to your mates. Of course, careful consideration must be given to the properties of the completed supply, and after talking to a few of my friends who have built their own and fallen into all the traps, here are the printable ones : RF proof, easy to make, commonly available parts used, but above all CHEAP.

Well, last things first. Breaking down the construction costs of a heavy duty regulated supply, they are in order:

  • The transformer (around $A80)
  • The main filter electrolytics – around $A80
  • The case – a metal case is well beyond the workshop capabilities of many amateurs and is quite expensive to buy (if you can).
  • The meter – around $A20-$27 (either digital or analogue)
  • The electronics – transistors, resistors, diodes, etc.
  • All the bits – fuseholders, terminals, switches, solder tags, nuts and bolts, power cords, etc.
    • Continue reading[...]

    Low drop Regulator with Indicator

    Posted by Unknown at 4:45 PM Friday, November 7, 2014 Labels: , , , , 0 comments
    Even today much logic is still powered from 5 volts and it then seems obvious to power the circuit using a standard regulator from a rectangular 9-V battery. A disadvantage of this approach is that the capacity of a 9-V battery is rather low and the price is rather high. Even the NiMH revolution, which has resulted in considerably higher capacities of (pen-light) batteries, seems to have escaped the 9-V battery generation. It would be cheaper if 5 volts could be derived from 6 volts, for example. That would be 4 ‘normal’ cells or 5 NiMH- cells. Also the ‘old fashioned’ sealed lead- acid battery would be appropriate, or two lithium cells.
     
    Circuit diagram : 
    Low-drop Regulator with Indicator Circuit Diagram
     
    Using an LP2951, such a power supply is easily realised. The LP2951 is an ever- green from National Semiconductor, which you will have encountered in numerous  Elektor Electronics designs already. This IC can deliver a maximum current of 100 mA at an input voltage of greater than 5.4 V. In addition to this particular version, there are also versions available for 3.3 and 3 V output, as well as an adjustable version.  In this design we have added a battery indicator, which also protects the battery from too deep a discharge. As soon as the IC has a problem with too low an input voltage, the ERROR output will go low and the regulator is turned off via IC2d, until a manual restart is provided with the RESET pushbutton.
     
    The battery voltage is divided with a few resistors and compared with the reference voltage (1.23 V) of the regulator IC. To adapt the indicator for different voltages you only need to change the 100-k resistor. The comparator is an LP339. This is an energy-friendly version of the LM339. The LP339 consumes only 60 µA and can sink 30 mA at its output. You can also use the LM339, if you happen to have one around, but the current consumption in that case is 14 times higher (which, for that matter, is still less than 1 mA).
     
    Finally, the LP2951 in the idle state, consumes about 100 µA and depend- ing on the output current to be deliv- ered, a little more.
    Continue reading[...]

    VOLTAGE REGULATOR MODULES VRM A SOLUTION FOR CPU CORE VOLTAGE ELECTRONIC CIRCUIT

    Posted by Unknown at 12:58 AM Monday, November 3, 2014 Labels: , , , , , , , , , , 0 comments
    VOLTAGE REGULATOR MODULES (VRM) A SOLUTION FOR CPU CORE VOLTAGE ELECTRONIC CIRCUIT

    For each phase, the components on point (2) above which constitute all the power components are placed on a small plug-in board of 1.15? x 0.85? that delivers 40 Amps and receives the PWM TTL signal from the controller. This module has a footprint of about 0.85? x 0.25? of the motherboard space and may be placed anywhere on the board as close as possible to theCPU reducing the transmission impedance and losses and giving the Motherboard designer the flexibility to optimize the power and PCB space utilization. Each modular board may be fitted individually with its own heat sink.
    Continue reading[...]

    VOLTAGE REGULATOR MODULES VRM A SOLUTION FOR CPU CORE VOLTAGE ELECTRONIC CIRCUIT

    Posted by Unknown at 12:58 AM Labels: , , , , , , , , , , 0 comments
    VOLTAGE REGULATOR MODULES (VRM) A SOLUTION FOR CPU CORE VOLTAGE ELECTRONIC CIRCUIT

    For each phase, the components on point (2) above which constitute all the power components are placed on a small plug-in board of 1.15? x 0.85? that delivers 40 Amps and receives the PWM TTL signal from the controller. This module has a footprint of about 0.85? x 0.25? of the motherboard space and may be placed anywhere on the board as close as possible to theCPU reducing the transmission impedance and losses and giving the Motherboard designer the flexibility to optimize the power and PCB space utilization. Each modular board may be fitted individually with its own heat sink.
    Continue reading[...]
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