Saturday, August 20, 2016

Potential for Evaporative Precoolers

In the last post we described a possible configuration for an evaporative precooler to lower total air conditioning operating costs at the expense of some additional capital costs (ducts, heat exchanger, evaporator) and perhaps a little additional maintenance costs on those items.   Of course, in order to make a decision on the payoff time, you have to know your climate conditions, your equipment costs, your operating costs, and the potential savings from the addition of the evaporative cooler.  In this post, we’ll provide a fuller description of the potential benefit you might be able to expect from an evaporative cooler for given inlet conditions.

Saturday, July 23, 2016

An Evaporative Pre-cooler

We talked in an earlier post about evaporative cooling and how you can use it to cool off air by simply evaporating water.  Evaporative coolers work best in dry climates, and are much cheaper to operate than vapor compression systems since there is no electricity-hungry compressor.  Unfortunately, they result in a large increase in the relative humidity of the air which may render it unacceptable for some indoor air applications.  In this post we’ll talk about how evaporative coolers are used in combination with other air conditioning equipment to lower the overall cost of providing conditioned air.

Saturday, June 25, 2016

Fundamentals of Thermal Resistance


The Thermal Resistance Analogy
Thermal resistance is a convenient way of analyzing some heat transfer problems using an electrical analogy in order to make complicated systems easier to visualize and analyze.  It is based on an analogy with Ohm’s law which is:
In Ohm’s law for electricity, “V” is the voltage which drives a current of magnitude “I”.  The amount of current that flows for a given voltage is proportional to the resistance (Relec).  For an electrical conductor, the resistance depends on the material properties (copper tends to have a lower resistance than wood, for example) and the physical configuration (thick short wires have less resistance than long thin wires).

Saturday, May 21, 2016

Error using constant specific heat

In the last post we looked at picking a value to use for cp when we make the constant specific heat approximation.  In this post, we’ll look more closely at the error involved in that approximation in order to have a feel for when it is appropriate, or not, to use it.

Saturday, April 16, 2016

Which cp to use?

In an earlier post we talked about the variation of specific heat with temperature.  Today we’ll explore that variation in more depth and consider the choice of temperature at which to evaluate specific heat.

Saturday, March 12, 2016

Water Lost Through Breathing, Part 2

In the last post we talked about the water loss from breathing and used the assumptions of exhaled air being at 92 deg F and 90% relative humidity, and inhaled air close to freezing, to develop a constant to estimate the water loss per hour for any breathing rate. This time, we’ll look at the effect of temperature and relative humidity and elevation on that constant.

Saturday, February 13, 2016

Water Lost Through Breathing

Have you ever wondered how much water you lose by breathing? Do you think that it is more or less than that lost through sweating? Most of the time when we breathe, we are exhaling moister air than we breathe in. There might be a few exceptions, but normally our bodies are losing a little bit of moisture with every breath. In this blog, we’ll try to quantify that moisture loss, at least in a ballpark way.