<div dir="ltr">Wow. Thank you! <br>Michael O'Brien started me on this the other day in a private message, and I very much appreciate both of these tutorials. I have to study this more to fully absorb all of it. But this is an excellent introduction. <br></div><div class="gmail_extra"><br><div class="gmail_quote">On Fri, Jan 2, 2015 at 10:29 AM, Topher <span dir="ltr"><<a href="mailto:topher@greenfret.com" target="_blank">topher@greenfret.com</a>></span> wrote:<br><blockquote class="gmail_quote" style="margin:0 0 0 .8ex;border-left:1px #ccc solid;padding-left:1ex"><span class="">On 12/27/2014 3:26 PM, Reuben Deumling wrote:<br>
> I'm a little fuzzy on all of these parameters. I know the<br>
> terminology but am not clear on the exact relationships, for<br>
> instance, between temperature and (relative) humidity and the<br>
> dewpoint. Anyone have a good primer they can recommend?<br>
<br>
</span>Challenge accepted. On the principle that one doesn't know a thing<br>
until one can teach it, [and to make up for getting it totally backwards<br>
once on this list.]<br>
<br>
Basic fact #1: The amount of water vapor that air can hold is limited,<br>
that limit is dependent on temperature, and it is not a linear<br>
relationship.<br>
<br>
Saturation Point: When the air (at its current temperature) is holding<br>
all the water vapor it can.<br>
<br>
Psychrometric Chart: A graph with dry bulb temperature on the X-axis,<br>
Humidity Ratio on the Y-axis, Saturation point curve on the left side,<br>
and various other metrics plotted on it (including wet bulb temperature,<br>
enthalpy, relative humidity, specific volume, dew point temperature,<br>
etc.). Atmospheric pressure is also a factor, so they are calibrated<br>
for a given elevation.<br>
<br>
Metrics (unit type given in parenthesis)<br>
<br>
Dew Point (temperature): The temperature at which air (at it current<br>
level of water vapor) will be at its saturation point. Dew point is a<br>
measure of absolute humidity (though the scale is not linearly related<br>
to either mixing ratio or partial pressure).<br>
<br>
Relative Humidity (percentage): For a given temperature, the percentage<br>
of the amount of water vapor actually present, compared to what it would<br>
take to be at the saturation point.<br>
<br>
Absolute Humidity [Mixing Ratio] (mass / volume): The mass of the water<br>
vapor in a volume of air.<br>
<br>
Dry Bulb Temperature (temperature): Standard temperature, named to<br>
differentiate it from Wet Bulb Temperature.<br>
<br>
Wet Bulb Temperature (temperature): Temperature read from a thermometer<br>
with a wet sock on it, being swung through the air. Sling psychrometers<br>
are generally how it comes. This can be used to determine humidity<br>
levels (in conjunction with a psychrometric chart). Wet Bulb<br>
temperature is closely correlated with Enthalpy but don't worry about that.<br>
<br>
Humidity Ratio: (mass of water vapor / mass of dry air) Another measure<br>
of absolute humidity.<br>
<br>
<br>
So, looking at a psychrometric chart (there are plenty on the web) for<br>
your elevation, you can find your current conditions by locating the<br>
current temperature on the x-axis, and the humidity level, either by wet<br>
bulb or relative humidity (depending on your measuring device) to<br>
establish a point on the Y-axis. Wet bulb lines slope negatively (down<br>
to the right) on the chart. Relative humidity (since it is a percentage<br>
of saturation temperature) follows the saturation curve.<br>
<br>
Warming the room involves moving that point to the right.<br>
Sensible cooling (only) involves moving the point to the left.<br>
Humidifying (only) involves moving it up.<br>
Dehumidifying (only) involves moving it down.<br>
Evaporative cooling moves it up and left.<br>
Chemical dehumidifying moves it down and right.<br>
<br>
If the point ever hits saturation curve, there is danger of<br>
condensation, and further movement in that direction will need to follow<br>
the curve. For example if one is cooling (only) and reaches the<br>
saturation point, further cooling is only possible by condensing some<br>
moisture out of the air.<br>
<br>
Looking at the chart tells us that your 60% at 70°F is a dew point of<br>
56°F. Extending that point to the left, it hits 90% RH at 59°F, so the<br>
temperature outside needs to be lower than that for air mixing to reduce<br>
your inside humidity.<br>
<br>
If the temperature outside is, say, 40°F at 90%RH, that is a dew point<br>
around 38°F, warming it to 70°F gives it a relative humidity of 30%.<br>
Mixing can be approximated by averaging the humidity ratio, so 50%<br>
inside air at 60%RH and 70°F, and 50% outside air at 90% RH and 40°F,<br>
mixed, and heated to 70°F, gives humidity ratios of 0.0096 and 0.0048<br>
respectively, and a mixed relative humidity around 46%.<br>
<br>
<br>
Thank You Kindly,<br>
<br>
Topher<br>
<div class="HOEnZb"><div class="h5"><br>
--<br>
Topher Belknap<br>
Green Fret Consulting<br>
Kermit didn't know the half of it...<br>
<a href="http://www.GreenFret.com/" target="_blank">http://www.GreenFret.com/</a><br>
<a href="mailto:topher@greenfret.com">topher@greenfret.com</a><br>
</div></div></blockquote></div><br></div>