Explanation 1
-------------
Temperature is average energy, mostly k.e. (kinetic energy) of molecules
Some molecules are in higher energy levels than some (faster)
Energy of one molecule is distributed (via entropy) in the degrees of freedom (from energy levels of electrons, rotational energy of the molecule, translational energy, oscillation/spring energy in bonds)
When breeze (air molecules) hits the liquid, the air is forces to flow tangential to the liquid surface
The source air also has molecules that are in various energy levels, however much of the energy is in bulk translational energy in the same direction (somewhat ordered)
At the boundary of the liquid and air, molecules from both interact
Some molecules of the the liquid gain enough translational k.e. to be ripped from the liquid. This would be mostly the molecules that had a higher energy level.
There is also a higher probability of evaporation than condensation due to the higher concentration of water molecules in sweat that in the breeze.
This loss of higher energy molecules to evaporation lowers the average energy
The rest of the bulk translational energy is passed to ordered low frequency sound that travels out of the liquid and air, and not absorbed as heat
Also, the fewer molecules in the boundary that gain k.e. (not resonating with the bulk sound) and do not escape to vapor eventually disperse that ke to the other degrees of freedom, and thus eventually have less ke and contribute slightly to heating, while the cooling effect described before dominate.
Also, the water molecules that go into the air are less volatile than normal steam molecule, and as its ke energy dispersed in its molecule's degrees of freedom it makes it cooler for an air mixture molecule. Humidity increases slightly.
Explanation 2
-------------
Nicola Tesla had believed that everything was based on vibrations
Imagine the breeze was a big sine wave (like sound). Almost no interaction would occur with the sweat to cause heating or cooling as the low frequency sound wave would just pass through. To achieve this the wind would start soft, move just the first layer (of molecules in the sweat) together, and so increase as the load increase (molecule increasing squeeze onto its neighbor in cumulating layers), without disturbing the overall orientation of the molecules in the sweat. Just picture a big sound wave passing through from air to liquid
Now consider normal breeze (it is far from a sin wave), this would be a broadband spectrum of frequencies in comparison (many frequencies of energy). The sweat surface has molecules of different energy frequencies, and can receive at their level of energy frequency
When the breeze and sweat interact. Some of the breeze frequency is absorbed by the sweat via matching some of the input frequencies (energy level) and load. The majority is reflected back as turbulence, and some still passes through as sound. The molecules that received energy via load balance will evaporate, thus still reducing the average energy of the sweat
Imagine this question: why does waves push away sand but not a very big rock
When a big tidal wave hit a megalithic rock, it would take immense energy for the rock to move like the wave, many atomic bonds would have to be broken simultaneously
Instead what happens is the rock produce a reactive force of much higher frequency (molecular bonds = strong potential & short distance) that energy "incoming" is "resonated out" at a higher frequency which then causes turbulence in the wave and the waves energy is not transferred to movement of the rock.
(Tesla said that we can view everything as frequencies and vibrations)
Let's act on what we agree on now, and argue later on what we don't.
Black men leave Barbeque alone if Barbeque don't trouble you