 |
Description  |
|
|
This invention relates to apparatus for collecting and retaining solar
energy as heat, and more particularly to apparatus which collects solar
energy on an absorption surface and uses water as the heat retention
medium. Preferably, the invention will be incorporated into a structure of
a permanent nature and thus, it will be called a "structure for collecting
solar energy".
A primary object of the invention is to provide a novel and improved
structure for collecting solar energy which effectively uses water, or any
other suitable liquid, not only to retain the heat generated from the
sun's rays, but also to serve as a medium for removing the heat generated
at the absorption surface as it receives the sun's rays.
Another object of the invention is to provide a novel and improved
structure for collecting solar energy and retaining the same as heat in a
body of water, which is adapted to direct water against an energy
absorption surface in an effective, efficient and simple manner.
Another object of the invention is to provide, in a novel and improved
structure for collecting solar enrgy as heat upon an absorption surface,
an arrangement for flowing water over the absorption surface which will
minimize the re-radiation losses and permit the operation of collecting
the solar energy to proceed in the most efficient manner possible.
Another object of the invention is to provide a novel and improved
structure for collecting solar energy which is especially suitable for
greenhouses, industrial processes, car washers and the like.
Other objects of the invention are to provide a novel and improved
structure for collecting solar energy which is economical, simple and
reliable, which can be built from commonly available materials at a
minimum of cost, capable of competing with conventional types of heating
apparatus; and which can be easily used in conjunction with other
structures.
With the foregoing and other objects in view, my invention comprises
certain constructions, combinations and arrangements of parts and elements
as hereafter described, defined in the appended claims, and illustrated,
in preferred embodiment, in the accompanying drawing in which:
FIG. 1 is a perspective view of a solar energy collector structure built
according to the principles of the present invention;
FIG. 2 is a transverse section through the collector as from the indicated
line 2--2 at FIG. 1;
FIG. 3 is an isometric fragmentary view of a ridge section of the collector
with portions of the cover sheet broken away to further exemplify the
manner in which the unit is built; and
FIG. 4 is a fragmentary sectional detail as taken from the indicated line
4--4 at FIG. 1 but on a further enlarged scale and with the water sprays
being diagrammatically indicated to exemplify the operation of the unit.
The threat of a continuing fuel shortage has brought about an extensive
development of apparatus designed to collect and use solar energy. One
feature of a common type of such apparatus consists in the use of a sheet,
or the like, to form a heat absorption surface to receive and absorb the
sun's rays. As the temperature on this sheet forming the heat absorption
surface rises, the heat is removed by a fluid, either air or water,
flowing past the sheet. The fluid, then warmed, may be used directly such
as for a hot air or a hot water supply, or such heat energy may be
transported and stored as in a tank or in a body of rocks or the like.
Most solar heating systems use air as the fluid for transporting the heat
of solar energy although the use of water in such a system for both the
transportation and storage of heat energy appears to be more desirable
because of the high specific heat capacity of water as compared with air
and other materials. However, the use of water has had serious
limitations. For example, an important limitation resides in the
difficulty of subjecting the sheet forming the heat absorption surface to
a uniform flow of water and the difficulty in effectively spreading the
water over the entire surface of the sheet. Another limitation resides in
the fact that evaporation of water can cause serious heat losses,
formation of salt and scale deposits in the apparatus. Also, corrosion can
be a problem in such a system.
The present invention was conceived and developed with such and other
considerations in view and the invention comprises, in essence, a
structure for collecting solar energy having one wall formed as a
properly-oriented, inclined solar absorption surface which is protected by
transparent membranes of suitable material. The solar absorption surface
is an opaque, preferably black, plastic sheet. Solar energy is absorbed at
its outer surface. The structure also includes other walls arranged to
completely enclose it, with such walls being insulated to minimize heat
losses therefrom and waterproofed and vapor-proofed at the inside to
prevent the escape of water vapor therefrom. A water flow against the
undersurface of the heat absorption sheet, to remove heat from that sheet
as fast as the sun's rays generage the heat, is effected by a spray
designed to wet all parts of the sheet surface. The water flows from the
sheet and into a collector basin at the floor of the structure in a
continuous manner and the heated water may be stored in the basin or
flowed to a reservoir tank or other facility.
There will be a 100 percent humidity within the structure because of the
spray against the absorption sheet and all portions of the walls will be
damp while the apparatus is operating. This, however, will create no
special problems because of the waterproof and vapor-proof construction
and the flow of water to the floor basin will not lose any of the heat
collected at the absorption sheet.
It was discovered that this mode of collecting heat was very efficient.
Water can be circulated from the bottom of the reservoir, or the bottom of
the basin, where the coldest layers of water will be found, and this
colder water will be sprayed against the absorption sheet to hold the
absorption sheet at a minimum possible temperature while it is imparting
solar-generated heat to the water. This results in a minimum of
re-radiation of energy from the absorption sheet since the losses of heat
from the absorption sheet, as by re-radiation, are related to the
temperature of the sheet itself. Also, the spray action against the
underside of the sheet can be controlled to permit the water to fall away
from the sheet as droplets as the water temperature increases and no
portion of the water will remain upon the sheet for an excessive length of
time. A natural decrease in viscosity of water as it is heated will assist
in this action. It is to be noted that the water used for this purpose may
include a detergent or similar wetting agent to better wet the underside
of the absorption sheet and that, if desired, this water may also include
other additives such as an anticorrosion agent. Also, whenever the
absorption sheet is of a type which permits infra-red radiation to pass
through it and into the structure, the droplets will absorb the energy of
such radiation.
Another advantage in the collection of heat by the spray action resides in
the fact that droplets of water produced by the spray action which do not
strike the absorption sheet but which fall through the air as a mist or
rain, will absorb heat from the air within the structure to impart heat to
the water in the base. Thus, should portions of the surface of the
absorption sheet not be effectively wetted by the spray, the air within
the structure will nevertheless pick up heat from such sections of the
absorption surface by convection which, in turn, is absorbed by the
droplets of water falling to the basin within the structure.
To further set forth the features and advantages of the invention,
reference is made to the drawings which exemplify a preferred embodiment
thereof. As shown at FIG. 1, the primary feature of the structure is the
solar wall S which is designed and oriented to receive the sun's rays. As
such, this solar wall is preferably rectangular in form, oriented in a
general east-west direction to face the sun from the south, and inclined
from the vertical at an angle which is selected to lie normal or
approximately normal to the sun's rays whenever the sun is at a specific
altitude. This will depend upon the latitude where the structure is to be
located and a specific time of year, such as at the winter soltice. A
skilled surveyor or other artisan can select a proper inclination for any
selected location and condition. This inclination of the solar wall S from
the vertical wall will vary throughout the country and will be from
20.degree. to 50.degree. in latitudes encompassing the continental United
States. Actually, it is not essential; in fact, it is impossible, to
position the solar wall S such that it is always normal to the sun's rays.
However, a suitable absorptive surface can absorb the sun's rays even when
the absorption sheet is inclined from the normal, although there will be a
reduction in the effective area which receives the sun's rays. Thus, the
flat, inclined solar wall S mounted in a fixed position, facing south, can
receive the sun's rays for a substantial portion of a day even though its
efficiency decreases when the sun's position is in the east or west
portion of the sky.
With the inclined solar wall S, a natural form of the structure is
tent-like, with a complementary sloping north wall N opposite the solar
wall S and triangular end walls E and W at the east and west ends of the
building to complete the enclosure. It is to be noted, however, that the
north wall need not have the same slope as the solar wall S, nor for that
matter, the structure need not be tent-shaped, as illustrated, providing
that the structure is enclosed. Thus, this structure may be a rectangular,
box-like unit or in any other suitable form, the tent-shape being
preferred only because of an economy of material and a natural, structural
rigidity. The structure may also be a portion or an annex to an existing
building where such is suitable for the purpose at hand. The structure is
completed by a floor section F which includes a basin B and it is to be
noted that the north wall, end walls and the floor F are not only rendered
vapor-proof, but they are also insulated to prevent heat loss as
hereinafter described.
In this preferred embodiment, the solar wall S is formed between the end
walls E and W by an array of spaced-apart rafters 20 inclined from a ridge
21 to a sill 22 at the base of the wall. Thus, solar energy absorption
panels are formed between the end walls and adjacent rafters 20 and
between other rafters 20 as illustrated. It is contemplated that each end
wall E and W will also have a corresponding rafter-like member, not shown,
such as a rafter 20 at its inner face to facilitate attachment of
components thereto as will be hereinafter described. Each rafter 20, which
may be a structural 2 .times. 4 or similar beam, is stabilized laterally
by a diagonal network of wires 23 extended across each panel in a regular
array, the wires being fastened to the top surface of each rafter and also
the top edges of the end walls E and W in any suitable manner.
The energy absorption sheeet 25 is extended across each panel between the
rafters 20 and this sheet 25 is preferably black colored and of a plastic
material such as polyethylene. A black, high density polyethylene sheet
0.004-inches thick was found to be suitable for the purpose and such
material is easily available. Such a sheet has not heretofore been
considered entirely suitable because it will not completely absorb infra
red radiation but in the present invention, radiation into the structure
will be absorbed by a spray of water as previously mentioned. This
absorption sheet 25 is stretched and mounted in place by being fastened to
the underside of each rafter and a single sheet may be stretched across
the entire reach of the solar wall S from one end wall to the other. A
slat 26 may be used at the underside of each rafter 20 and the rafter-like
members at the end walk help hold the sheet in place. Some wrinkling of
the sheet is inevitable when the sheet is fastened in place even with the
slats helping to hold the sheet. Once in place, however, a natural
shrinking of the sheet will occur to stretch it taut.
Where the structure is of appreciable size, such as where the rafters 20
are 20-feet high, a single polyethylene sheet sufficiently wide to overlay
the rafters cannot be obtained and 4 foot webs of the sheeting may be lap
welded together to form the sheet 25. In doing so, it becomes desirable to
orient the lapped edges horizontally with a downturned lip 27 at each
joint to facilitate the removal of water from the sheet by dripping, as
illustrated at FIGS. 3 and 4.
The energy absorption sheet 25 must be protected from the exterior air to
prevent heat from being removed by convection currents and a cover is
provided by two layers 30 and 31 of sheets of clear polyethylene or a like
resin which is quite transparent to the sun's rays, especially the rays in
the infra-red range. The two layers are attached to the top edge of each
rafter and the top edges of the end walls to space them away from the
absorption sheet 25 and they are held in place by slats 32 upon the
rafters and upon the end walls. One or more thimbles 33 are provided at
each rafter, between the layers 30 and 31 to provide air communication
between the layers to hold them in place as will be described. The manner
in which the two layers 30 and 31 are attached to the top edge of each
rafter may be varied somewhat depending upon the construction procedures
being used. For example, a slat, not shown, similar to slats 32, may be
located between the layers 30 and 31 so that the layer 30 may be placed
before the layer 31 is placed above the layer 30. With this arrangement,
the thimbles 33 would not be necessary since a gap in the spacer slat
could provide the same function of communication permitting airflow
between the sheets from one panel to another.
It is to be noted that the lower layer 30 rests upon the diagonal wire
network 23 and the spacing of the wires is such as to hold this layer
above, and out of contact with, the absorption sheet 25 whenever the sheet
is bellowed downwardly by air pressure between the sheets as now
described.
The use of one heat transmission as a cover is possible but the two sheets
30 and 31 more effectively insulate the solar wall S from heat loss from
absorption sheet 25. To provide an effective insulation, these
transmission sheets 30 and 31 are held apart by air pressure to provide an
air gap between them. Also, another air gap exists between the lower sheet
30 and the absorption sheet 25 since the lower sheet 30 is prevented from
touching the absorption sheet 25 by the wire network 23. A small air pump
34 is mounted on a side wall E of the structure which has a discharge
passage which communicates with the space between the heat transmission
sheets 30 and 31 to blow air into the panels to spread the sheets apart.
This airflow from one panel to the next will be through the thimbles 33.
Although the sheets 30 and 31 will be stretched fairly tightly over each
of the several panels, they will billow apart responsive to a very small
air pressure, as in the manner best shown at FIGS. 2 and 3. The air
pressure may be less than 1 pound per square foot. When the sheets 30 and
31 are so spread by air pressure between the layers, the structure is
ready for use as a solar energy collector.
The remainder of the structure, the north wall and the triangular east and
west walls, and the floor section may be built in a conventional manner,
providing that the same are rendered waterproof and vapor-proof and are
well insulated. Preferably, the north wall N may be sloped oppositely to
the slope of the solar wall S as illustrated, although as heretofore
mentioned, this is not essential. The north wall may be formed of rafters,
not shown, extending from the ridge 21 to a sill plate 22' and the space
between the rafters will be carefully insulated as by insulation 35. Also,
it is essential to provide a roof cover sheet 36 at the outer side of this
north wall for weather protection. An impermeable inner sheet 37 is
provided at the inner side of this wall which is both waterproof and is a
vapor barrier. This waterproofed vapor barrier is necessary because the
structure must withstand high humidity and excessive moisture which will
occur within the structure when it is in operation as will be described. A
number of commercial companies provide waterproof plastic and asphalt
sheets which are also effective vapor barriers.
The end walls E and W may be built in a similar manner using vertical
studs, not shown, with insulation between the studs. The outer wall 38,
indicated at FIG. 1, is a conventional weatherproofed wall, and the inner
wall 39, indicated at FIG. 2, is vaporproof, the same as the cover sheet
37 heretofore described. Also, as illustrated at FIG. 1, a suitable
doorway and door 40 may be provided in one of these vertical walls such as
a wall E, for access to the interior of the structure.
The floor F is likewise built in essentially a conventional manner. It is
preferably made of reinforced concrete to provide structural strength
sufficient for the basin B to be filled with water. The concrete may be of
an insulating type, but if not, an insulating layer, not shown, may be
extended above, or underneath, the floor F and the basin B to prevent heat
loss into the ground. Also, it is essential that this floor F and basin B
be waterproofed and vapor-proofed the same as the north wall and end walls
of the structure. A vapor barrier sheet 41 will extend over the entire
floor and basin structure, as illustrated at FIG. 2 and join with the
other vapor barrier sheets 37 and 39 and with the absorption sheet 25. The
basin B will be over the sloping solar wall 25 and a walkway 42 may be
provided at the north side of this basin, at the floor section under the
north wall N.
This structure for collecting solar energy is completed by providing a
suitable spray system adapted to direct sprays of water against the heat
absorption sheet 25. In the arrangement best illustrated at FIG. 2, a
water pump 43 at one end of the structure has its intake 44 at the bottom
of the basin and the discharge line 45 extends upwardly therefrom to a
manifold 46 which, in turn, connects with an array of spray pipes 47
extending in spaced parallelism longitudinally across the structure behind
the solar wall S the length of the building. Each distributing pipe 47 is
equipped with an array of nozzles 48 as illustrated at FIGS. 2 and 3, the
nozzles 47 being spaced along the pipes 46 so as to direct a fine spray of
water against the underside of the absorption sheet 25. As illustrated at
FIG. 2, the distributing pipes and the nozzles are arranged to wet the
underside of this absorption sheet over its entire area. Preferably, the
distributing pipes 46 are spaced from top to the bottom of the structure
in a pattern which corresponds with the seam lips 27 so that the water
directed to the underside of each end portion of the sheet will run off at
the seam lip 27 after it flows down the sheet and across the web portion
forming the seam lip 27. The direction of the spray is illustrated in the
drawings as being normal to the absorption sheet 25. However, it is to be
noted that this spray could be directed at an angle with respect to the
absorption sheet and the spraying could be horizontal or even vertical
providing it strikes the absorption sheet to keep the sheet wet.
As the water drips from the heat absorption sheet, it will fall into the
basin B. An insulating cover float 49 may be placed in this basin to help
reduce heat loss from the stored water when the structure is not in
operation, such as at nighttime. The insulating cover float 49 is
preferably made of expanded, polystyrene foam or polyurethane closed-pore
foam or such materials that are very light in weight and have excellent
insulating properties. The portions of the cover sheet, or sheets, is such
that the basin is substantially covered, excepting for edge portions to
permit water to flow from the upper surface of the cover sheet to the
basin and the upper surface of the cover sheet is sloped in any suitable
manner to facilitate such flow.
It is to be noted that in the operation of this apparatus, the spray within
the structure will cause essentially a fog of water and a considerable
amount of water and spray will be directed against the underside of the
absorption sheet 25. Thus, with sunshine, this water will be continually
heated by removing heat from the absorption sheet. For a most effective
operation, the base of the intake 44 of the pump 43 will be near the
bottom of the basin B where the water will be cooler because of the
greater density of the cool water. As the water flows down the absorption
sheet, it is heated and falls, as droplets, into the basin B. Thus, the
warmer water will be near the top of the basin. As this water is warmed
up, it may be utilized in a number of ways. The water from the basin B may
be piped to another structure or to a storage tank by distributing lines
from the basin which are not shown. The warmed water may even be
permanently removed from the basin. In any event, an outlet conduit from
the basin will be located near the upper level of the basin to take the
water as it is warmed by solar action. Such an outlet conduit can be
attached to the floating cover in order to be located at the warmest
portion of the tank water, regardless of the possibility of the water
level varying within the tank. It is to be noted that the high humidity
and fog of water within the structure will not detract from the
effectiveness of the operation of the apparatus so long as the structure
is enclosed and vapor-proofed since, then heat loss by evaporation will
not be a factor in the operation of the structure.
From the foregoing description, it is apparent that this structure can be
constructed as a large building capable of collecting a large quantity of
solar energy, capable of heating commercial installations. Also, the
structure may be used at the top of commercial buildings for heating the
building. To demonstrate the effectiveness of the moderately sized unit, a
structure for collecting solar energy was built having a solar wall S
191/2 feet high and 951/2 feet long with an effective area of about 1850
square feet. A charge of 2,000 gallons of water at a temperature of
59.5.degree. F. was warmed to a temperature of 112.5.degree. F. in a short
period of time and it was estimated that the heat collected was 886,120
(British thermal units) BTU. In another test using 6,162 gallons of water,
the water was heated from 75.degree. F. to 95.degree. F. in a short period
of time and it was estimated that 1,029,820 BTU of heat were collected in
the day's run. Clearly, the structure can operate effectively and it can
be used to heat the various structures such as buildings. It appears that
the apparatus is especially adapted for use with greenhouse structures
which must be heated during the winter months in many portions of the
country.
The efficiency of the unit is further enhanced by the droplets of water
falling through the air within the structure. The air within the structure
will be heated by the absorption membrane, especially at portions where
the spray may not effectively strike it. Likewise, some droplets of water
from the spray will not strike and wet the membrane but will form a mist
or fog in the structure before falling into the basin. Such droplets will
absorb heat from the air within the structure to enter the basin at an
increased temperature along with water dropping from the absorption
membrane.
While we have now described our invention in considerable detail, it is
obvious that others skilled in the art can build and devise alternate and
equivalent constructions which are nevertheless within the spirit and
scope of our invention. Hence, we desire that our protection be limited
not by the constructions illustrated and described, but only by the proper
scope of the appended claims.
* * * * *
|
|
 |
|
 |
Description |
|
