Beginner ham radio power supply

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Many of us have accumulated various power supplies from laptops, printers or monitors with a voltage of +12, +19, +22. These are excellent power supplies that have protection against both short circuit and overheating. Whereas in home, amateur radio practice, an adjustable, stabilized source is constantly required. If it is not advisable to make changes to the circuit of existing power supplies, then a very simple prefix to such a unit will come to the rescue.

Will need


To build an amateur set-top box with continuously adjustable output voltage, we need:
  • - a ready-made module on the lm2596 chip;
  • - mounting box;
  • - two nests with an internal diameter of 5.2 mm;
  • - potentiometer 10 kOhm;
  • - two permanent resistors 22 kOhm each;
  • - panel ampere voltmeter DSN-VC288.

The article will consist of several finished parts, each of which will describe in detail the steps, features and pitfalls of the components used.

DC-DC buck converter on the lm2596 chip


The lm2596 microcircuit, on which the module is implemented, is good in that it has overheating protection and short circuit protection, but it has several features.
Look at the typical version of its inclusion, in this case, the microcircuit of the editorial output fixed voltage +5 volts, but for the essence it does not matter:

Maintaining a stable voltage level is ensured by connecting the feedback output of the fourth (Feed Back) leg of the microcircuit connected directly to the output of the stabilized voltage.
In the particular module under consideration, the version of the microcircuit with a variable output voltage is applied, but the principle of regulating the output voltage is the same:

To the output of the module, a resistive divider R1-R2 is connected with the upper trimmer resistor R1 turned on, introducing the resistance of which, the output voltage of the microcircuit can be changed. In this module, R1 = 10 kOhm R2 = 0.3 kOhm. The bad thing is that the adjustment is not smooth and is carried out only on the last 5-6 turns of the tuning resistor.
To implement a smooth adjustment of the output voltage, the ham enthusiasts exclude the resistor R2, and the trimming resistor R1 is changed to alternating. The scheme goes like this:

And just here, a serious problem arises. The fact is, during the operation of a variable resistor, sooner or later, the contact (its contact with the resistive horseshoe) of the middle output is broken and the output 4 (Feed Back) of the microcircuit appears (albeit for a millisecond) in the air. This leads to an instant failure of the chip.
The situation is also bad when conductors are used to connect a variable resistor - the resistor turns out to be remote - this can also contribute to the loss of contact. Therefore, the standard resistive divider R1 and R2 should be unsoldered, and instead of it, soldered two constants directly on the board - this solves the problem of loss of contact with a variable resistor in any case. The variable resistor itself should be soldered to the soldered terminals.
In the diagram, R1 = 22 kOhm and R2 = 22 kOhm, and R3 = 10 kOhm.

On a real diagram. R2 was the resistance corresponding to its marking, but R1 surprised me, although it is marked with 10 kOhm in fact, its nominal resistance was 2 kOhm.

Remove R2 and place a drop of solder in its place. Remove the resistor R1 and turn the board upside down:

Solder two new R1 and R2 resistors guided by a photo. As you can see, the future conductors of the variable resistor R3 will be connected to three points of the divider.
That's it, put the module aside.
Next in line is a panel ampere voltmeter.

Voltammeter DSN-VC288


The DSN-VC288 is not suitable for assembling a laboratory power supply, since the minimum current that can be measured with it is 10 mA.
But the ampervoltmeter is great for assembling an amateur design, and therefore, I will use it.
The view from the back is as follows:

Pay attention to the location of the connectors and the available adjusting elements, and especially to the height of the current measurement connector:

Since the case I selected for this homemade product does not have sufficient height, I had to bite the metal pins of the DSN-VC288 current connector, and solder the attached thick conductors directly to the pins. Before soldering, make a loop at the ends of the wires, and by soldering each on each pin, solder - for reliability:

Scheme


Schematic diagram of the connection of the DSN-VC288 and lm2596


Left side of the DSN-VC288:
  • - the black thin wire does not connect to anything, insulate its end;
  • - yellow thin connect to the positive output of the lm2596 module - LOAD "PLUS";
  • - red thin connect to the positive input of the lm2596 module.

Right side of the DSN-VC288:
  • - black thick connect to the negative output of the lm2596 module;
  • - red thick will be LOAD "MINUS".

Final assembly of the block


I used the mounting box with dimensions of 85 x 58 x 33 mm .:

After marking with a pencil and a dremel disk, I cut out the window for the DSN-VC288 to fit the inside of the device. At the same time, at first I sawed the diagonals, and then sawed off individual sectors along the perimeter of the marked rectangle. We’ll have to work with a flat file, gradually adjusting the window under the inner side of the DSN-VC288:

In these photos, the cover is not transparent. I decided to use transparent later, but it doesn’t matter except transparency, they are absolutely identical.
Also, outline the hole for the threaded collar of the variable resistor:

Please note that the mounting ears of the base half of the box are cut off. And on the chip itself, it makes sense to stick a small radiator. At my fingertips were ready, but it’s not difficult to cut a similar one from a radiator, for example, an old video card. I sawed a similar one for installing a laptop chip on a PCH, nothing complicated =)

Mounting ears would interfere with the installation of these 5.2mm sockets:

In the end, you should get exactly this:
At the same time, on the left is the input jack, on the right is the output:

Check


Apply power to the set-top box and look at the display. Depending on the position of the axis of the variable resistor volts, the device may show different, but the current should be at zeros. If this is not the case, then the instrument will have to be calibrated. Although, I read many times that the factory has already done this, and nothing will have to be done from us, but still.
But first, pay attention to the upper left corner of the DSN-VC288 board, two metallized holes are designed to set the device to zero.

So, if without load the device shows a certain current, then:
  • - turn off the console;
  • - securely close these two contacts with tweezers;
  • - turn on the prefix;
  • - remove the tweezers;
  • - disconnect our set-top box from the power supply, and reconnect it.

Load test


I do not have a powerful resistor, but there was a piece of a nichrome spiral:

In the cold state, the resistance was about 15 ohms, in the hot, about 17 ohms.
In the video, you can watch the tests of the resulting set-top box just for such a load, I compared the current with an exemplary device. The power supply was taken at 12 volts from a long-gone laptop. The video also shows the adjustable voltage range at the output of the console.

Total


  • - the prefix is ​​not afraid of a short circuit;
  • - not afraid of overheating;
  • - not afraid of open circuit adjusting resistor, when it breaks, the voltage automatically drops to a safe level below one and a half volts;
  • - the prefix is ​​just as easy to withstand if the input and output are mixed up when connected - this happened;
  • - there is an application for any external power supply from 7 volts and up to 30 volts maximum.

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Watch the video: Ham Radio Basics--Jim, W6LG Sets Up a Basic Ham Radio Station (December 2024).