Solar Radiant heat question

Re: Solar Radiant heat question

Also, don't get too wrapped up with Evacuated Tube type solar thermal collectors...

They are great for very cold weather and very hot water output... But for a price/performance value--standard box with cover glass type thermal collectors may give you more heat overall.

Also, interestingly enough--One of the potential issues with Evac Tube collectors is that they are too well insulated... Snow falls on them, and it takes forever for it to melt off.

With the glass box type, there is enough heat loss that the snow melts off by itself and the collector will gather more BTU's because it is fully exposed to sun while the evacuated tubes are still covered with snow.

Here are couple of things to look at (from another post of mine):

Solar Thermal can be a nice source for space heating and hot water... And usually is "cheaper" per kWhr/BTU vs Solar PV Electric. Also, Solar Thermal lends itself very well to do it yourself projects. Note, these are plumbing projects and have their own issues (leaks, pump failures, installation issues trapping air, anti-freeze, storage, heat exchangers, etc.):

Solar Shed and other Solar Thermal Links

A good place to start reading is Home Power Magazine... They have a free past issue online--and have a lot of articles you can read for free. I don't always agree with them and their reviews--but they are a fun and enlightening read:

Home Power Mag

-Bill

Re: Solar Radiant heat question

It has been decades since I had to do my Thermal calculations from college--So I am not going to say "never"... But at some point you probably will hit the laws of dimisishing returns... If you need 4-5x the amount of solar thermal collectors to get an extra 100 heating days a year (all made up numbers)--then it becomes a real $$$ of installation costs (and added maintenance) vs the avoid fuel costs.

I grew up on the coast just south of San Francisco CA... Lots of trees and marine layer (my little valley, 4 days of heavy overcast, 2 days of sun during the "summer"... Back during the 1970's oil shocks--There were people coming in to sell solar hot water collectors even in our area... Never heard of any successes and most were gone within a couple years (these were simple batch heaters from what I remember).

Or to quote somebody who can write in English:

"The coldest winter I ever saw was the summer I spent in San Francisco."
--probably not written by Mark Twain

Since you have an existing system--You can run your own experiments with a flow meter and a couple thermometers...

Take a day you are interested in and run several flow (low to high) rates and document the temperature increase from inlet to outlet... You should be able to graph a curve that shows how many BTU/kWH per square foot of panel you are currently getting... And lay that against the vendor's performance curves...

Obviously, the slower you move the water, the higher the temperature--but since water flow is so slow, you get very little heating effect. That is the point at which heat loss (from a hot panel) equals heat gain (from a weak sun)... And see if you can match that against the performance curves of other collectors.

-Bill

Re: Solar Radiant heat question

You might be able to play with the system--Get a liquid flow meter (such as from an old swimming pool setup) and plumb in a valve to restrict flow to a particular value--then measure/plot the results...

And yes, it will probably not be a linear graph--You will probably see a fixed BTU per hour high very high flow rates and the BTU/Hr value falls as flow rates are reduced and the temperature approaches the stagnant temperature (flattens to zero BTU per hour) of the collector.

It would be interesting to see what you find out... There are so many competing factors (temperature rise, convection, conduction, radiation, etc.) all of which have their linear, squared, 5th power etc. effects your installation.

And you are probably correct--you run the risk they will tell you want they think you want to hear.

The technology is probably "cheap enough" that you could purchase a few tubes (used?) and a flat plate collector and run your own tests.

-Bill

Re: Solar Radiant heat question

Todd,

I hope that you find the following helpful... Sometimes I type the answer to a question that was never asked--So be kind... I am trying (my wife says I am trying too).

Depending on what your flow meter is calibrated in (I am thinking of something like one of these--you have to find ones that cover your expected flow range). Or, for a short experiment you can even use a "calibrated" 5 gallon bucket (if you are using plain water) and dump 5-10 gallons into the buck in X minutes...

So, lets assume that you do from from 0.1 gallon to 10 gallons per minute flow rate.

1 gallon of water weighs ~8.35 lbs. So 10 gallons of water weighs 83.5 lbs (per 10 gallons).

And you will be doing these measurements in degrees F (Fahrenheit). And BTU (British Thermal Unit) is the amount of energy it takes to raise 1 lb of water 1 degree F.

So, lets say you start on a cloudy day (say high overcast in the middle of the day so that you can run several tests with similar weather conditions) with 10 gpm (gallons per minute) flow on your 120 sqft solar collector... So you set your flow rate to maximum and find out that it fills your bucket with 10 gallons of water per minute. And you find out that the temperature increases 1 degree F... How much heat did you collect... By the way, if you want you can convert this to kWatt*Hours (1kWH equals 3413 BTU) (note, obviously these numbers are made up--but I did size them very roughly for what I would expect your solar thermal array to produce in cloudy weather).

I don't know your controller and what exactly displays--but here is an example of how you would manually log the data for three differing operating points.

• 10 gpm * 8.35 lbs per gallon * 60 min per hour * 1.0 F temperature rise = 5,010 BTU per Hour
• 5,010 BTU per hour * 1/3,413 BTU per kWH = 1.47 kWatt heating rate

Now, lets do 1.0 GPM and assume you get an 8F rise:

• 1 gpm * 8.35 lbs per gallon * 60 min per hour * 8.0 F temperature rise = 4,008 BTU per Hour
• 4,008 BTU per hour * 1/3,413 BTU per kWH = 1.17 kWatt heating rate

And then, the same thing at 0.1 gpm and assume you get a 40 F temperature increase:

• 0.1 gpm * 8.35 lbs per gallon * 60 min per hour * 40 F temperature rise = 2,004 BTU per Hour
• 2,004 BTU per hour * 1/3,413 BTU per kWH = 0.59 kWatt heating rate

So, you now have a few data points that show you how much heat you get on a cloudy day... Do the same thing on a clear day, and at a couple different temperatures (hot day vs cold day)...

With your system, I guess it does recirculate water, so you have the ability to observe system performance with different inlet water temperatures... A set of logs may include the following:

Temperature Ambient / Input / Output / Low-Med-High speed / BTU.Hr or kWH output

40F / 60F / 61F / High / 1.0 kW
40F / 60F / 64F / Med / 0.8 kW
40F / 60F / 68F / Low / 0.3 kW

Then wait for the weather to change to a hotter day (say 60F) and run the same tests...

The problem is that you don't have a thermal reference point for how much sun light you are getting... You can get a pyrometer to measure actual heat content from the sun, or you can use a simple solar cell/small panel and a DMM set to Amps (or mAmps--depending on size of panel).

Build your own solar irradiance meter

Within a reasonable level of accuracy, the short circuit current from a solar cell represents the amount of solar energy you are getting (at least in the light/UV range of the silicon cell).

From your location, you would assume 0.0 as "dark" and perhaps 80.0 mAmps on a sunny/clear summer day. If you get 20.0 mAmps on a cloudy day, then your solar irradiation is 20/80 or 25%. Typically a bright/sunny day is around 800-1,000 kW per square meter (you may have the solar cell/panel information and it will tell you the output current at 1,000 Watts per sqmeter--High Noon sun).

And you can compare how much useful heat you get from your 25% day and figure out how many more sq.ft. of panels you wish to add... And if your system outputs very little Watts (or BTU/Hr) on a cold/overcast day--then 3x a very little amount of energy is still a little amount of energy.

Then you can look at the performance specifications for an evacuated tube
module and see if your setup (out door temperature, flow rate, output temperature) and figure out what a 10 tube array would output in similar conditions.

So, now that I went into way to much detail about how to understand the performance of your current system--Here is a set of charts from a evacuated tube type collector manufacturer:

www.thermomax.com/Efficiency.php

So, on the last page, if you want a 40F rise in temperature on a 0C day (32F) on a 200 W/sqmtr (roughly 20% sunlight) then the efficiency would be (very roughly--goes off the end of the chart) 20%...

So, for 120 sqft of evacuated tube collectors is 11.1 sq meters:

• 200 w/sqmtr * 11.1 sq meter * 0.20 eff = 444 Watts output

Is that a lot or a little compared to your existing setup and is 444 Watts worth the $$$ to purchase install?

I don't know--that is your call....

Anyway, that is how I would perform an experiment on my system (if I had one) and wanted to look at how to collect more heat.

I hope that helps, and I did not confuse you or myself even more.

-Bill