Daniel LIGHTFOOT - Solar Collector

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**Daniel LIGHTFOOT**

 

**"Hot-Line" Solar Heat Collector**



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[**http://www.motherearthnews.com/Renewable-Energy/1976-05-01/The-Hot-Line-Solar-Collector.aspx**](http://www.motherearthnews.com/Renewable-Energy/1976-05-01/The-Hot-Line-Solar-Collector.aspx)

# The Hot-Line Solar Collector

*By the
Mother Earth News editors*

  

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Like many backyard inventors, Dan Lightfoot of Sigourney,
Iowa has been interested in alternate energy concepts for some
time about 22 years, as a matter of fact. Unlike most of his
peers, however, Dan has managed to make a major breakthrough
in his field -- one which even has the "experts" shaking their
heads in disbelief.

That breakthrough is the Hot-Line solar collector you see
pictured in the Image Gallery. At first glance, the Hot-Line
module looks just about like a conventional flat-plate
collector. What makes Lightfoot's panel highly unconventional
is that it [1] contains a
specially curved reflector which acts to concentrate
incoming sunlight on a wedge-shaped absorption tube, [2]
operates with an efficiency far surpassing that of any
"normal" flat-plate solar panel, and [3] actually "tracks"
the sun through a 50 degree "vertical arc and through 150
degrees in the "east/west plane without moving!

Impossible? That's what a University of Iowa physics
professor said when Dan Lightfoot first explained the design
to him. Rest assured, though, the device does work, and rather
well, at that.

So well, in fact, that Lightfoot (after selling exclusive
manufacturing rights on his invention to the Iowa City-based
NRG Corporation) has recently been able to quit his job with a
mining firm and devote full time to energy research. Lightfoot
now heads up an outfit called Aerco, which is short for
Alternate Energy Resources Company.

Dan Lightfoot came upon the idea for the Hot-Line collector
quite by accident a decade ago. It seems Dan had been
observing a sheet of aluminum that was resting up against his
garage wall and noticed how the sun's reflection from that
curved sheet formed a bright spot on an adjoining wall.
Moreover, he noticed that the bright spot stayed in roughly
the same place throughout the day, despite the sun's constant
movement.

This got Dan to thinking, and to experimenting. With the aid
of a small sheet of aluminum, a few scraps of wood and a
handful of bolts and clamps, Lightfoot found (by trial and
error) that he could curve the metal in such a way that it
would focus light in a line -- a line that, furthermore, moved
only a small distance in or out from the metal as the
jury-rigged reflector was tilted through various angles to the
sun.

At this point, Dan knew that if he could just bend a long
sheet of reflective material to the same curvature, lay a
channel along the focal plane of the reflector thus created,
and run air or water through that channel, he'd have what no
one had developed before: a fixed-position, concentrating
solar collector. (Focusing collectors are nothing new, of
course, but they all have one drawback: in order to work, the
reflector must face squarely into the sun at all times. This
usually calls, in turn, for a costly and complex motorized
gimbal mounting, to allow tracking of the sun. In contrast, Lightfoot's collector can focus
light all day long while remaining stationary -- a
"major breakthrough" indeed!)

So, in his spare time, Dan built models and refined them over
a period of years until he felt he had optimized all aspects
of the unorthodox solar panel's design. The end result was the
Hot-Line solar collector.

Measuring 26 1/2-by-96-by-10
inches, the production version of the Hot-Line module has a
surface area of 16.1 square feet. Nestled in the unit's sturdy
aluminum frame or chassis (see Fig. 1 above) is a pre-shaped
block of styrofoam which serves to [1] insulate the structure
and [2] hold the reflector a a sheet of mirror-finish
aluminum --  in the proper curvature. Laid along the deepest
part of the reflector's curve is the triangular-section
aluminum absorption tube. (The wedge shape is necessary in
order to accommodate the lengthening and shortening of focal
lengths as light enters the panel at different angles.)
Finally, covering the surface of the panel is a sheet of
Kalwall Sun-Lite fiberglass glazing, which Lightfoot claims
"deflects very little incoming sunlight, even at oblique
angles."

How does the Hot-Line collector work? As you can see in Fig.
2 (see Image Gallery), when sunlight enters the panel at a
nearly perpendicular angle (such as would occur around
sunrise) the reflector focuses incoming rays of light either
on the outermost edge of the absorption tube or the part
closest to the reflector itself, depending on whether the
incident light enters the collector's upper portion or lower
portion. As Ole Sol rises higher in the sky, the focal line,
or "hot line," hitting the top surface of the absorption wedge
moves closer to the reflector --"while the hot line on the
aluminum extrusion's underside moves away from the reflector
sheeting. Not until the sun is more than 60 degrees above the
horizon, or better than 75 degrees displaced to the east or
west, does the incoming light fail to focus or become "blanked
out" by the chassis itself.

What this means in the case of a vertically mounted,
south-facing unit is: the Hot-Line collector [A] starts
working as soon as the morning sun peeks over the horizon, [B]
continues to concentrate light energy all day until the sun
rises more than 60 degrees (that is, a good deal more than its
maximum winter height) above the horizon, and [C] does so at
continuously high efficiency. (At the moment, Dan Lightfoot is
not advertising any particular set of numbers when it comes to
the efficiency of his collector, but preliminary tests by
others in the field point to
heat-recovery percentages in the very high 80s or low 90s
-- which is about double the efficiency of most commercial
flat-plate collectors.)

Thus, it's easy to believe Dan Lightfoot when he confidently
states that just one of his 16-square-foot Hot-Line panels is
sufficient to provide total daytime heating for one room in an
average house. "Some rooms heat up more than others,"
Lightfoot explains, "depending on the degree of insulation,
volume of air to be heated, and so on. However, you might like
to know that one fellow in Kaloma, Iowa heats a room with a
single Hot-Line module, and that room doesn't have any
insulation or even any wallboard! Still, the 140-degreeA air
coming out of that collector warms the place right up."

So far, Aerco and NRG have installed a total of 18 Hot-line
units in Iowa, all of them air-heating (as opposed to
water-heating) models. That is, in each of these installations
a blower is used to force room air through the collector's
absorption tube and straight back again into the room, without
"tapping into" a heat storage reservoir at any point. (A water
system employing heat storage is, however, under development
at present and will be on the market soon.)

How does Dan Lightfoot like spending all of his time (and
most of his cash reserves) on energy research, after giving
decades of his adult life to a career in the coal-mining
industry? "I'm happier doing what I'm doing now, trying to
wake people up to the possibilities of alternative energy
sources, than I've ever been," he proclaims. "I wouldn't
trade the satisfaction I'm receiving now for anything in the
world!"

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SOLAR HEAT COLLECTOR MODULE  
CA1043206

1978-11-28

Abstract

A solar heat system is comprised of a panel or bank of heat
collector modules each of which has a fluid-carrying tube of an
elongated triangular shape in transverse cross section formed
with longitudinally extended inwardly projected heat radiating
fins. A tube is mounted within a concavo-convex reflector of a
hyperbolic form such that the side walls of the tube are
subjected to reflected rays of solar radiation over an effective
range of solar exposure of about one hundred and fifty (150 deg)
degrees.

The reflected rays are concentrated in a longitudinally
extended focal zone on each side wall of the tube and these
zones of concentrated solar radiation move transversely of a
side wall in response to the angle of the solar rays falling
upon the reflector.

![](f12.jpg)  
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![](f5.jpg)![](f6.jpg)  
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 ![](f9.jpg)![](f10.jpg)

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COLLECTOR MODEL OF SOLAR HEATING  
GR64911

SONNENWAERME-AUFFANGMODUL  
DE2658717

SOLAR HEAT COLLECTOR MODULE  
AU2074876

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