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In the past, various systems have been devised in an effort to obtain a
relatively inexpensive energy source for heating of enclosed building
structures, hot water for various uses, and the like. Most of these
systems have been plagued with either complete unreliability, with
unacceptable fluctuations in available temperatures or such gross
inefficiency as to not be able to justify the initial capital outlay for
construction of the same.
Additionally, various systems and components thereof attempting to capture
a maximum amount of energy from solar sources have been disclosed. These
systems, however, have not been highly efficient in operation for the
simpler devices and the more complex systems, although having more
efficiency, are economically unpractical because of their complexity and
cost. Also, maintenance and adjustments become extremely critical in the
more complex systems which further detract from their economical operation
and thus wide spread acceptance.
Further, solar heat use integrated into present conventional heating
systems has not been shown to be practical or satisfactory.
After much research and study into the above mentioned problems, the
present invention has been developed to provide a highly efficient solar
energy collecting device which functions at peak efficiency throughout the
day and automatically recycles during normal sundown periods to be in
proper position for the next operative cycle. The system of the present
invention also provides for a constant heat source over an extended period
of time whether heat is being transferred into the system during that
period or not. Additionally, the system of the present invention provides
for a relatively constant temperature heat source so that the enclosure
being heated will remain at a constant predetermined temperature in a
manner similar to conventional heating systems.
When using the present solar heat exchanger system in combination with
standard oil furnace or electric heated homes, a complete system is
provided which gives 24 hour comfort with a minimum of fuel cost outlay to
accomplish this. Thus, ti can be seen that a complete system is provided
and not just desirable components with installation and systematizing
being left to the prospective purchaser.
In view of the above, it is an object of the present invention to provide a
highly efficient system for collecting and storing solar energy for use in
heating enclosures and other desirable uses.
Another object of the present invention is to provide a solar heating
system which is thermostatically controlled for even temperature over
extended periods of time.
Another object of the present invention is to provide, in a solar energy
collecting system, a simple, inexpensive and yet highly efficient means
for obtaining maximum exposure to solar radiation during the hours of
availability of the same.
Another object of the present invention is to provide a solar collecting
and heating system which is readily installable in any area where direct
rays of the sun fall for a substantial part of the day.
A further object of the present invention is to provide a solar heating
system which is relatively inexpensive to construct and install and yet is
highly efficient and extremely economical in operation.
Other objects and advantages of the present invention will become apparent
and obvious from a study of the following description and the accompanying
drawings which are merely illustrative of such invention.
IN THE DRAWINGS
FIG. 1 is a front perspective view of the solar energy collector and
exchanger of the present invention;
FIG. 2 is a rear perspective view of the same;
FIG. 3 is a sectional view taken through lines 3--3 of FIG. 2;
FIG. 4 is a partial sectional view taken through lines 4--4 of FIG. 1;
FIG. 5 is a schematic of the overall system of the present invention;
FIG. 6 is an electrical schematic of the collector-exchanger rotating
drive; and
FIG. 7 is a sectional view taken through lines 7--7 of FIG. 2.
With further reference to the drawings, the temperature controlled system
of the present invention, indicated generally at 10, is composed of a heat
exchanger unit 11, a heat storage means 12 and an enclosure or other means
13 to be temperature controlled. When incorporated into the system of the
present invention, these last three mentioned portions of the system are
interconnected and controlled as will hereinafter be set forth in more
detail.
Referring more specifically to the heat exchanger unit of the present
invention, a support means comprising a pair of generally parallely
disposed longitudinal frame members 14 and 15 have fixedly secured
laterally across the ends thereof frame members 16 and 17. A backing
surface 18 composed of plywood, sheet metal or the like is provided.
Interiorly of backing surface 18 is an insulating material 19 to prevent
excessive heat loss. A layer of foil material 20 is provided on the
opposite side of insulation 19 from backing 18.
Pairs of sides 21 and 22 and ends 23 and 24 are provided which are fixedly
secured to the frame members heretofore mentioned and the backing 18 to
provide a box-like structure. A transparent heat retaining surface 25 such
as clear pastic, glass or the like is provided across the portion of the
box-like structure hereinabove defined opposite backing surface 18.
Extending from the area adjacent foil surface 20, toward transparent
surface 25, are a plurality of elongated, ridge-like heat exchanger
surfaces 26 as can clearly be seen in the FIGS., particularly FIG. 4. Each
of the surfaces 26 is preferably composed of sheet metal and can be
secured to the heat exchanger 11 along ends 23 and 24.
Heat exchange tubes 27 are provided between transparent surface 25 and heat
exchange surfaces 26 as can clearly be seen in FIGS. 1 and 4. These heat
exchange tubes are preferably U-shaped in a zig-zag pattern adjacent the
heat exchange surface 26 so that two portions of the tube lie adjacent
each peak of surfaces 26 and two portions of such tube lie adjacent each
valley as can clearly be seen in FIG. 4. Tube 27 can either be a
continuous tube bent to the configuration described and shown or can be a
plurality of elongated tubes with U-shaped or manifold end portions.
Whichever form is used would be left to the convenience of the
manufacturer, considering cost and manfacturing time economics.
All surfaces, including the heat exchange tubes 27 and the heat exchange
surfaces 26, that can be viewed through transparent window 25 are
preferably painted with a heat absorbing paint such as flat black.
For manufacturing purposes, the heat exchange surfaces 26, heat exchange
tubes 27 and the transparent surfaces 25 can be constructed as a panel
unit of convenient handling size such as 4 by 8 feet and the box-like
enclosure defined by backing surface 18, sides 21 and 22 and ends 23 and
24 can be made of such a size to accommodate either one panel, two panels,
three panels, and so forth. In constructing the readily handable panels,
indicated generally at 28, structural support means would, of course, be
provided but these are felt to be well known to those skilled in the art
and further description of the same is not deemed necessary.
Each of the solar panels 28 has an inlet portion 29 to tube or conduit 27
and an outlet portion 30. The inlet portion of each of the panels is
operatively connected to an inlet line 31. Each of the outlet portions of
each solar panel is operatively secured to an outlet line 32. As shown in
the drawings, both the inlet and outlet lines are preferably insulated to
prevent undesirable heat loss during flow of a heated fluid therethrough.
Inlet line 31 is operatively secured to a standard valve means 33 and
outlet line 34 is operatively secured to a similar valve means 34.
Exchanger unit inlet line 35 is connectingly secured to valve 33 and
exchanger unit outlet line 36 is connectingly attached to valve 34.
The reason for the inlet and outlet lines passing through valve means 33
and 34, respectively, is so the exchanger unit 11 and the exchanger tubes
27 therein can be precharged with a fluid such as water, antifreeze, or
other heat transfer media which will eliminate the problem of air in the
lines of the system when installed. The advantage of this will hereinafter
become more obvious.
To further aid in the absorption of solar energy, a plurality of reflector
panels 37 are provided which are fixedly secured to sides 21 and 22 as
well as ends 23 and 24. These reflector panels are, for the size solar
panels hereinabove described, preferably approximately 18 inches in width
and 8 feet in length. Each reflector has been found to operate at optimum
when disposed at an angle of approximately 20.degree. outwardly from their
respective side or end. Each of these reflectors is preferably either
white or silver colored to reflect maximum rays into the blackened
surfaces of the heat exchanger 11. Brackets 38 are provided, as seen
clearly in FIGS. 1 and 2, to secure the reflector panels 37 to the
respective sides and ends of the exchanger unit 11.
To support, move and properly orientate exchanger unit 11, a tripod-shaped
support stand comprising legs 39, braces 40 and central support shaft 41
are provided. Rotatively mounted on shaft 41 is a support sleeve 42.
Fixedly secured to this support sleeve is a spur gear 43. To protect this
gear from the elements, a housing 44 is provided thereabout. Fixedly
secured to and mounted on one of the support legs 39 is a source of
rotative power such as electric motor 45. This motor is operatively
secured to gear box 46. This gear box, as well as motor 45, are of
standard construction, are readily available on the market, and further
discussion and details of the same are not deemed necessary.
The power output shaft 47 of gear box 46 has gear 48 fixedly secured
thereto. Gear 48 is designed for meshing engagement with gear 43.
Support sleeve 42 has a unit support shaft 49 fixedly secured thereto and
terminating at its upper end (as oriented in the drawings) at a
semi-cylindrical sleeve 50 which is fixedly secured thereto. A second
semi-cylindrical sleeve 51 is provided. Each of these two last mentioned
sleeves have outwardly projecting flanges 52 and 53 which lie juxtaposed
to each other and are held in releasably secured relation by means such as
bolts 54. The reason for this arrangement is to allow the heat exchanger
unit 11 to be shipped separate from its support means and then secured
thereto on location.
Rotatively mounted between the two adjacent semi-cylindrical sleeves 50 and
51 is a cross support shaft 55 which is fixedly secured at its ends to
longitudinal frame members 14 and 15 as can clearly be seen in FIG. 2.
Thus from the above it can be seen that the heat exchanger unit 11 can be
tilted about the axis of cross support shaft 55 and can be rotated about
the axis of unit support shaft 49.
A spacer or tilt support 56 is provided which is toggly connected at one
end to lateral frame 17 and at the other end to one of the support legs 39
as can clearly be seen in FIG. 2. This tilt support is preferably
longitudinally adjustable so that the distance between leg 39 and frame 17
can be varied. Any one of a number of well known means for accomplishing
this such as telescoping rods, helically threaded shafts and sleeves or
the like can be used.
The tripod legs 39 and support shaft 41 of the exchanger unit support
indicated generally at 57 can, if desired, be embedded in the ground in
concrete to stablize the same. With this type of installation, it has been
found that the exchanger of the present invention can withstand gale force
winds of 60 or more miles per hour without damage or misalignment.
Mounted within housing 44 (or at some other convenient location) is a timer
switch 59 such as the AMF Paragon 25000 series program time switch. This
timer can be set to one minute increments so that current can be allowed
to pass therethrough for a very short interval with a predetermined
opening of short or day interval.
Electrical current from a power source (not shown) passes through line 58
into programmable timer 59. Line 60 connects to motor 61 with a return
line 62 to the above-mentioned power source. Thus it can be seen that
through use of the sophisticated program time switch 59, motor 61 can be
alternatively energized and deenergized to slowly, through gear box 46 and
spur gear 43, rotate the heat exchanger unit 11 about the axis of shaft
49. When the timer is properly set, the said exchanger unit can follow the
movement of the sun from early morning to late evening for maximum direct
exposure.
Because the tilt support 56 is togglely mounted to a single support leg 39
and off center from the axis of the shaft 49, the tilt of the heat
exchanger unit 11 is maximum when said leg is in perpendicular alignment
with frame 17 and is at a lesser angle of tilt when on either side of
perpendicular as seen particularly clear in FIG. 7.
Referring more specifically to FIG. 5, the insulated heat exchanger unit
inlet and outlet lines 35 and 36 lead into and from a storage means 12.
This storage means, although it could be in other forms, is preferably a
tank of 250 gallon capacity or greater and is heavily insulated preferably
with at least 6 inches of foam type insulation to allow only negligible
undesired heat loss therefrom. Inside the tank is preferably a plurality
of heat exchange coils 63 operatively connected between the inlet and
outlet lines 35 and 36 although it is, of course, understood that a liquid
such as water within the tank could be circulated through the inlet and
outlet lines and the heat exchanger unit. This has been found, however, to
be inferior to the use of the heat exchange coils in the storage means.
The reason the heat exchange coils are of superior benefit is that
antifreeze can be used in the enclosed system of the tank coils 63, lines
35 and 36 and the exchanger tubes 27 with a requirement of only a few
gallons of fluid while, if the liquid within the tank were circulated
through the heat exchanger, several hundred gallons would be required.
Also, the danger of freezing up during winter months of the relatively
exposed tubes 27 of the heat exchanger during periods of darkness or heavy
cloudiness requires supplemental heat from sources such as electric
heaters which consume tremendous quantities of energy. By using the
antifreeze charged coil system, the danger of fluid freeze up is
eliminated.
Another benefit of the anifreeze charged coil system is the heat exchanger
unit 11 can be precharged as can lines 35 and 36 and coils 63 so that when
the system of the present invention is placed on job site, all that is
requires is for seals to be broken and connection made to have a
completely enclosed fluid charged system ready for operation.
A low energy consuming circulation pump 64 is disclosed in one of the lines
35 and 36. This pump is preferably thermostatically controlled and is
connected to thermostat 65 by line 66. The thermostat, which as noted from
the drawings is located on the heat exchanger 11, is of the type that
makes on rising temperature and breaks on falling temperature. It has been
found through use that a setting of 150.degree. in winter and 165.degree.
in summer is adequate. Thus in the winter for example, when the
temperature within the heat exchanger unit 11 rises to 150.degree. or
above, thermostat 65 will energize circulation pump 64 to circulate fluid
through the heat exchanger 11 and back through the heat storage means 12.
As long as the temperature within the heat exchanger 11 remains above the
present 150.degree.,the circulation pump will continue to operate. When
the temperature drops below 150.degree.,as on heavily clouded or darkening
conditions, the thermostat 65 will break thus cutting off the circulation
from pump 64.
Water from a well pump, a City water main or other water source 67 is
preferably under approximately 40 psi pressure when it passes through
water line 68 and into the heat storage means or tank 12. Once the tank 12
is completely filled, additional ambient water from source 67 will only be
introduced as needed to keep the tank full. The primary depletion of the
water will be from the water heater as will hereinafter be described.
A water outlet line 67 leads from tank 12 to a low energy consuming
circulation pump 70, preferably of approximately 1/12 horsepower (as is
pump 64). This pump is controlled by thermostat 71 which makes on
temperature drop and breaks on rise as is the case with common household
and building heat control thermostats. The circulation pump 70 is
operatively connected to lines 72 which have space periodically hot water
heat registers 73 of any common well known design. Lines 72 terminate at a
juncture with water return line 74. This line circulates the somewhat
cooled water in lines 72 back into tank 12 as seen clearly in FIG. 5. Thus
it can be seen that as the temperature within the building or enclosure 13
drops below the present temperature on thermostat 71, circulation pump 70
will begin operating and circulate water through lines 72 and registers 73
and by line 74 back to heat storage tank 12 until the temperature within
the enclosure rises enough for thermostat 71 to cut circulation pump 70
off.
A valve means 75 can be provided in outlet lines 69 of tank 12 so that
water can be fed from such line directly into the inlet side of a standard
electric or gas water heater 76. As water is removed from the water heater
in the usual manner by the hot water faucet (not shown) of the plumbing
system (not shown) of the enclosure or building 13, additional heated
water from tank 12 will, under pressure, replace the water drawn off. So
long as the water within the storage tank 12 is at or above the
temperature set on the water heater, no current or energy will be consumed
even though hot water is being withdrawn through the heater. Whenever the
temperature of the water in the heat storage tank 12 drops below that set
on the thermostat (not shown) of the water heater, its standard heating
system will be activated in the normal manner. Even though the temperature
of the storage tank 12 is not as high as that set for the water heater 76,
the fact that the incoming water is at least partially preheated prior to
entering hot water heater (rather than cold water coming directly from a
well or outside water main) can amount over a period of time to a
substantial savings in water heating energy.
To use the system of the present invention, the heat exchanger unit 11 is
set up in proper orientation so that it can rotate from a direction facing
the rising sun to a direction facing the setting sun with maximum tilt at
the center or noon portion of these limits of travel. All motor and timer
wiring as well as circulation pumps and thermostats are installed by the
standard methods well known to those skilled in the art. All lines are
charged with fluid as described and all tanks and lines leading to and
from the same are filled and charged as the case may be. The system is now
ready for operation.
With the solar panels 28 of the exchanger unit 11 facing toward the sun,
the temperature in tubes 27 will rise above the preset temperature of
thermostat 65 thus starting circulating pump 64. The fluid within the
system will collect heat from tubes 27 of exchanger 11 and, through
insulated line 36, carry the same into the heat storage means or tank 12.
There heat will be exchanged through heat exchanger coil 63 to the medium
such as water contained therein thus raising the temperature of such water
while cooling the fluid within the coils. The cooled fluid will then
circulate back to the exchanger unit 11 through insulation inlet line 35
and into exchanger tubes 27.
Timer 59 will periodically energize motor 61 to, through gears 48 and 43,
rotate exchanger 11 in a time sequence to keep it pointing generally
towards the sun for maximum energy absorption throughout the day. As
earlier explained, the tilt support 56, because it is toggle connected off
center from the axis of shaft 41, will cause a cyclic tilting back and
forth of the exchanger 11 as it rotates about the axis of its shaft during
the predetermined day cycle. Thus the exchanger will be more flattened to
face the early morning and late evening sun and will be tilted more
upwardly toward the noon sun with infinite increments therebetween. The
reflector panels 37 aid further in capturing additional rays and thus
energy from the solar body to convert the same into heat energy.
If the day is extremely cloudy or upon the setting of the sun in the
evening, the temperature within lines 27 will drop to the point where
thermostat 65 of exchanger 11 will break thus cutting off circulation pump
64. Since this pump is low energy consuming, the fact that it operates
constantly when circulation temperatures are being achieved does not make
the system of the present invention uneconomical. To the contrary, the
amount of current used for any of the circulation modes described herein
is negligble.
Whenever it is deemed desirable to use the energy stored in stoage means
12, such as heating enclosure 13, the thermostat 71 therein is set to the
desired temperature. Whenever the temperature drops below this preset
point, circulation pump 70 is activated to circulate fluid from heat
storage means 12, through the interior heat exchangers 73, and back to the
storge means. When the interior temperature has reached the desired preset
level, thermostat 71 will break thus cutting off operation of pump 70.
As earlier discussed, valve 75 can be opened to either preheat the water
going into the water heater 76 or to actually prevent any energy being
expended by the normal heating elements thereof if the temperature of the
stored liquid (if the same is water) is equal to or greater than that at
which such heater is set.
As to the efficiency of the system of the present invention, a two panel
heat exchange unit has been found to raise the temperature in a 250 gallon
tank 40.degree. on an average winter day. A three panel heat exchange unit
is capable of furnishing, on an average winter day with only rare
supplementation, all of the heat required for a 750 square foot, two
bedroom apartment.
Although the system of the present invention has been described as
capturing, storing and using of solar generated heat, it has been found
that the heat exchanger in darkened conditions such as nighttime will
actually absorb coolness to a point some ten degrees colder than the
ambient air. On at least one occasion when water was being used as the
fluid in the system, the same froze when the ambient temperature was many
degrees above freezing. Because of this phenomena, switching valves 77 in
inlet and outlet lines 35 and 36 can be used at night to circulate the
cooled fluid into a cool storage means (not shown), identical in function
to storage means or tank 12, for cooling rather than heating. The
controlling thermostats 65 and 71 would have to be reversed, the former
making on the drop while the latter making on the rise. In summer, or in
climates with cool nights and warm days, the heat exchanger 11 with dual
thermostats and automatic switching valves can be used for both warmth and
cool energy absorption and storage for ultimate use within either
enclosure 13 or any other desired application.
In the cooling concept hereinabove discussed, the heat exchanger would, of
course, not need to be rotated or tilted and in fact if only cooling were
desired, the heat exchanger could be fixedly installed rather than as
hereinabove described.
Although the solar heat exchanger is shown and described as including a
plurality of relatively flat ridges and valleys, it is understood, of
course, that corrugated absorbing surfaces or even outwardly facing,
semi-cylindrical surfaces can be used with the heat exchange tubes 27
disposed longitudinally in the troughs thereof. Also a heat resistant
material such as asbestos can be placed between the absorbing surfaces 27
(whether flat as shown, corrugated or semi-cylindrical) and insulation 19.
From the above, it is obvious that the present invention has the advantage
of providing a relatively simple and inexpensive and yet highly efficient
solar energy operated heating system. It also, when not in use as a solar
system, can be converted to use a cool temperature collecting and storing
means.
The present invention may, of course, be carried out in other specific ways
than those herein set forth without departing from the spirit and
essential characteristics of the invention. The present embodiments are,
therefore, to be considered in all respects as illustrative and not
restrictive and all changes coming within the meaning and equivalency
range of the appended Claims are intended to be embraced herein.
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