Powering a small vent fan directly from a panel

To add to McGivor's comment...

Buck converters that higher voltage/lower current DC and efficiently down convert to lower voltage/higher current DC. For buck converters, the input voltage should be something like 1.5 volts, or higher, than the output voltage (i.e., 13 volts output, then >14.5 volts input).

There are also boost controllers... They take low voltage/higher current DC voltage in, and output higher voltage/lower current output.

And lastly, there are buck-boost converters, they take a wide range of input voltages that can be higher, the same, or lower than the output voltage.

Buck converters are getting so cheap these days, many are sold in lots of 4 or more to get near $20 USD to make money on the sale (some Amazon examples):

https://www.amazon.com/s?k=buck+converter+adjustable (buck)
https://www.amazon.com/s?k=buck+boost+converter+adjustable (buck boost)

Just make sure the input voltage is compatible with your solar panel/array (Voc (open circuit) and Vmp (max power)) are sensitive to temperature... Typically, on very warm days/full sun/hot panel, the Vmp~17.5 volts becomes closer to 15 or 14 VDC... And when the sun is not hitting the panel at right angles (morning/evening sun), the Imp (current max power) is less... By 50% or less than noon-time sun. And on sub freezing days, Voc/Vmp can rise upwards of 20% or so (over the name-plate rating).

Why does this matter? DC brush-less fans use electronics internally to operate... In "corner conditions" it is very easy to have over voltage from the solar panel ruin the fan... For example, you can use a 24 volt fan on "12 volt" panels (really Vmp~17.5 volt) panels and avoid the DC converter. But the fan will run slower/lower RPM than its name plate rating most of the time.

Lots of factors to juggle (how much air you want to move, fan voltage, array voltage, buck or buck-boost or boost converter, etc.). Electronic circuits can be very unforgiving at times (over voltage usually kills semi-conductors).

-Bill

panel -> converter -> fan

That is about it. No fuses required (fuses are there to protect the wiring from short circuits)... As long as your wire AWG rating is > Isc (short circuit) of the solar panel, and output current of the converter, fuses are not required.

Loads that run for many hours per day can be, surprisingly, energy hogs. For example, using your 3 amp maximum fan on a 225 AH 12 volt battery bank (remembering suggesting that you should plan on 25-50% discharge of battery capacity in "normal" operation--longer battery life):

• 3 amps * 12 hours per day = 36 AH
• 36 AH / 225 AH battery bank = 0.16 = 16% of battery capacity
• 225 AH * 25% (i.e., 2 days of storage) = 56 AH per day suggested "nominal" loads on battery bank
• 36 AH (12 hour worst case fan loading) / 56 AH per day = 0.64 = 64% of daily suggested battery usage

On sunny days, probably not a huge issue... But if fan runs over night, or there are a couple days of clouds/winter/etc., after 3-6 days, yes, the fan can easily take your bank dead. And is a significant load on a "small" solar power system.

In general, if you just need fan during daylight hours--A panel+fan (+converter) is a better solution. Battery powered devices--Just more things that can go wrong and/or using "expensive" battery+charger power to run a simple fan during the day.

-Bill

Voltage Drop Calculator for 12 volts 10 feet 3 amps:

https://www.calculator.net/voltage-drop-calculator.html?material=copper&wiresize=13.17&voltage=12&phase=dc&noofconductor=1&distance=10&distanceunit=feet&amperes=3&x=42&y=35

Voltage drop: 0.24
Voltage drop percentage: 2.01%
Voltage at the end: 11.76

Generally aim for ~1-3% voltage drop for wire run in solar. Looks OK.

DC rated contacts on timer...

Timer would usually only be used on DC Battery supplied fan--Unless you are specifically after temperature control... In any case, typically need to supply stable DC 12 volt battery power to timer circuit, if not the fan itself.

Place the converter near the fan if you want more precise voltage control... But no big deal either way. Some down converters are "more stable" with short wiring on the output. Long wiring is inductive and can cause "ringing" in the converter output leads.

-Bill

I am sorry JY, you did say thermostat, not timer...

There was a person here years ago that installed some solar attic fans, and his attic temperature did drop.

A few years later, he noticed that the fans had failed, but the attic temperature was still down... More or less, just adding additional venting (holes) was enough to do the trick. DC and Solar powered fans generally do not move that much air (10-35 Watts DC fan vs 200 Watt or so for a 120 VAC attic fan--2-3x or more airflow-CFM for AC versions?).

-Bill

This is the problem with "current sources" like solar panels...

A solar panel outputs current (mostly) in proportion to the amount of sunlight... So, say 4 amps in full sun from zero volts to Vmp (~18 volts).

When connected to a non-linear power device (like your DC to DC converter), once the solar input drops the available current below that required by the converter, then the output voltage collapses. Say Vpanel fall from 18 volts to 12 volts, all at 3 amps max input... Then a bit less sun, current falls below 3 amps. DC converter tries to draw more than 3 amps (because of falling panel voltage) and then collapses panel voltage to minimum input supported by supply:

• Say 3 amps @ 12 volts (made up numbers for example)
• P=V*I= 12 volts * 3 amps = 36 volts to fan
• Say >4 amps at panel, and panel will produce 0-18+ volts
• 18 volts * 4 amps = 72 Watts from panel (more than 36 watts for fan)
• 3 volts * 4 amps = 12 watts input to DC converter (less than 36 watts for fan)

So, you see "two stable" regions for panel--18 volts and 3 volts (as example).

That is the "Magic" MPPT does. It looks for the maximum output power from the array (18 volts * 4 amps)... And would only draw enough current from the panel to keep Vmp @ ~18 volts (~2 amps * 18 volts = 36 watts to fan).

But with "simple" DC to DC converters, they run into the issue where a cloud passes over, and the converter "stalls" trying to supply power to fan, but this power draw keeps the Vpanel voltage low--And it gets "stuck" until something changes.

Changes can include panel simply outputting more current and drawing Vpanel up. Another way is to interrupt the Fan Power (open switch and keep fan off), to let Vpanel get back to ~18 volts, then start fan again. And it is very possible that your DC converter can get into a "restart" cycle until there is "more sun" (fan starts, Vpanel is ~18 volts), or there is not enough sun, and Vpanel does not get to ~18 volts when fan starts, and voltage collapses again--Until sun sets).

-Bill