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Claims  |
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We claim:
1. A solar concentrating lens and receiver operable in alignment with
incoming sunlight, and including;
a multiplicity of parallel transparent elongated slats spaced apart in an
array for the passage of light and to ventilate therebetween for reducing
wind resistance, and each slat being of basic prism cross section with its
apex disposed outwardly from a projection plane aligned with the incoming
sunlight,
an elongated receiver longitudinally coextensive with and spaced from the
array and on said projection plane in parallel relation to each of the
slats,
and each of the slats having upper and lower sides inwardly divergent from
its apex and angularly related for projection of the incoming sunlight
through the slats and into the receiver, and having a base faced toward
the projection plane and angularly disposed for reflection of the incoming
sunlight through the spaces between the slats and into the receiver.
2. The solar concentrating lens and receiver as set forth in claim 1,
wherein the slats are spaced a distance apart to cast the light shadow
from the apex end of one slat to the edge at the lower side of the next
adjacent slat.
3. The solar concentrating lens and receiver as set forth in claim 1,
wherein the upper and lower sides of the slats are divergent to refract
the incoming sunlight into the receiver.
4. The solar concentrating lens and absorber as set forth in any one of
claims 1, 2 or 3, wherein an array of said parallel transparent elongated
slats extends symmetrically from opposite sides of the projection plane.
5. The solar concentrating lens and absorber as set forth in any one of
claims 1, 2 or 3, wherein each of said slats of basic prism cross section
has at least one of its sides cambered to focus incoming sunlight to a
focal plane within the receiver.
6. The solar concentrating lens and receiver as set forth in claim 1,
wherein the upper and lower sides of each of the multiplicity of parallel
transparent elongated slats are increasingly acute in angular relation
progressively toward the projection plane.
7. The solar concentrating lens and receiver as set forth in claim 1,
wherein the slats are spaced a distance apart to cast the light shadow
from the apex end of one slat to the edge at the lower side of the next
adjacent slat, and wherein the upper and lower sides of each of the slats
are increasingly acute in angular relation progressively toward the
projection plane.
8. The solar concentrating lens and receiver as set forth in claim 1,
wherein the upper and lower sides of the slats are divergent to refract
the incoming sunlight into the receiver, and wherein the upper and lower
sides of each of the multiplicity of slats are increasingly acute in
angular relation progressively toward the projection plane.
9. The solar concentrating lens and absorber as set forth in any one of
claims 6, 7 or 8, wherein the apex of each inwardly adjacent slat is
truncated to increasingly separate the upper and lower sides of the slats
progressively toward the projection plane, thereby increasing the beam
depth of the slats having increasingly acute related sides for rigidity.
10. The solar concentrating lens and absorber as set forth in any one of
claims 6, 7 or 8, wherein an array of said parallel transparent elongated
slats extends symmetrically from opposite sides of the projection plane.
11. The solar concentrating lens and absorber as set forth in any one of
claims 6, 7 or 8, wherein each of said slats of basic prism cross section
has at least one of its sides cambered to focus incoming sunlight to a
focal plane within the receiver.
12. The solar concentrating lens and receiver as set forth in claim 1,
wherein the upper and lower sides of each of the slats are increasingly
acute in divergent angular relation progressively toward the projection
plane and the upper sides thereof cambered to have a lens effect and
refract the incoming sunlight into focus at the receiver.
13. The solar concentrating lens and receiver as set forth in claim 1,
wherein the upper and lower sides of each of the slats are increasingly
acute in divergent angular relation progressively toward the projection
plane and the lower sides thereof cambered to have a lens effect and
refract the incoming sunlight into focus at the receiver.
14. The solar concentrating lens and receiver as set forth in claim 1,
wherein the upper and lower sides of each of the slats are increasingly
acute in divergent angular relation progressively toward the projection
plane and both the upper and lower sides thereof cambered to have a lens
effect and refract the incoming sunlight into focus at the receiver.
15. A solar concentrating lens and receiver--absorber operable in alignment
with incoming sunlight, and including:
a projection plane aligned with the incoming sunlight,
an array of transparent elongated slats disposed in parallel relation to
and from at least one side of the projection plane, said slats spaced
apart for the passage of light and to ventilate therebetween for reducing
wind resistance, and each slats being of basic prism cross section with
its apex disposed outwardly from the projection plane aligned with the
incoming sunlight,
an elongated receiver coextensive with and spaced from the array and on
said projection plane in parallel relation to each of said slats and
comprising a chambered body of transparent plastic having a window tube of
transparent glass of high temperature properties supported coextensively
within the chambered receiver body with an annulus therebetween and
forming an inner chamber to enclose an elongated absorber to receive
projected incoming sunlight,
the absorber extending coextensively within the receiver and spaced from
the array and on said projection plane in parallel relation to each of the
slats to receive projected incoming light,
and each of the slats having upper and lower sides divergent from its apex
and angularly related for concentration of the incoming sunlight through
said slats and into the receiver, and having a base faced toward the
projection plane and angularly disposed for reflection of the incoming
sunlight through the spaces between the slats and into the receiver and
onto the absorber.
16. The solar concentrating lens and absorber as set forth in claim 15,
wherein the receiver window is of slot formation to receive all projected
incoming sunlight.
17. The solar concentrating lens and absorber as set forth in claim 15,
wherein the receiver is internally reflective to capture and redirect rays
of light entering therein and onto the absorber.
18. The solar concentrating lens and absorber as set forth in claim 15,
wherein a reflective shield is disposed longitudinally coextensive within
the chamber body and embraces the absorber and restricts the window of the
receiver to a slot formation to receive all projected incoming sunlight.
19. The solar concentrating lens and absorber as set forth in any one of
claims 16 through 18, wherein an internally reflective shield is carried
within the chambered receiver body and slotted to receive incoming
sunlight.
20. The solar concentrating lens and absorber as set forth in any one of
claims 16 through 18, wherein the window tube of transparent glass is
supported co-extensively within the chambered receiver body with
insulation therebetween slotted to receive incoming sunlight.
21. The solar concentrating lens and absorber as set forth in claim 18,
wherein the shield is supported with structural insulation exterior
thereto.
22. The solar concentrating lens and absorber as set forth in claim 18,
wherein the shield is supported by structural insulation exterior thereto
and disposed between said shield and the receiver body to occupy the space
therebetween. |
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Claims |
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Description |
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BACKGROUND
Solar radiation is a prime source of energy, collected by means referred to
generally as "insolation", it being a general object of this invention to
efficiently capture heat energy from the sun rays by means of optical
concentration and fluid media absorption. Solar concentration is of
primary concern, it being the heat rays which are to be concentrated at a
focal plane with the least loss. The geometric concentration is to be, for
example, one hundred to one, whereby 500.degree.-700.degree. F. fluid is
produced from the absorber at pressure up to, for example, 700-800 p.s.i.
Heretofore, lens and mirror systems for insolation have been cumbersome and
space consuming, and the receivers and absorbers have been wasteful of
incoming light. That is, very large areas have been required for solar
collection, and there has been dispersion of otherwise useful light ahead
of and at the absorber target. It is acknowledged that the objective area
is a controlling factor which determines the quantity of light to be
collected and subsequently concentrated, and it is this area which is
minimized by the present invention by employing a "prism-lens" objective
array having a number of advantageous features as hereinafter described.
The optical concentration of light provided by the prism-lens array is
focused upon a plane within the receiver, entering therein through a
narrow slot-shaped window, to be captured within the internally reflective
confines of the vacuumized receiver and concentrated onto the absorber, as
will be described.
The "prism-lens" array which characterizes the solar light objective area
of the present inventive concept is comprised of a multiplicity of linear
light concentrators of slat configuration. It is an object of this
invention to concentrate light by focusing it upon the absorber plane,
utilizing each slat as a lens and for example a convex lens having camber
that focuses onto the absorber focal plane. It is the infrared heat rays
which have greatest heat value and which are of longer wave length focused
upon said absorber focal plane, while the ultraviolet light at the
opposite end of the spectrum and of shorter wave length is of less
effective heat value and is focused short of said focal plane. In
accordance with this invention, it is an object to concentrate the useful
solar light and especially the Yellow to Red light, Blue to Violet light
being marginally useful. Therefore, the receiver of this invention is
characterized by its "slot" window through which the useful solar light is
concentrated and focused upon the absorber focal plane. A feature is that
each slat is a prism-lens focused upon the absorber focal plane.
The slat prism-lens array as it is disclosed herein is similar to a Fresnel
Lens, and accordingly is a weight saving feature. However, this slat
prism-lens array must be exposed to the natural environment, namely the
wind element of the atmosphere, and it is wind gusts to which the
apparatus is subjected and to which it must be structurally resistant.
Accordingly, the slat elements of this lens array are spaced for
ventilation, but without sacrifice with respect to light collection
efficiency, the base of each prism-lens cross section being disposed so as
to reflect light through said space and onto the focal plane of the
absorber. Note that this spacing increases toward the opposite ends of the
array, the array being symmetrical about a central projection plane.
Efficiency of insolation requires minimized attenuation of incoming solar
light and reduction of re-radiation. Accordingly, it is an object of this
invention to provide an efficient prism-lens array and efficient
receiver-absorber combination. Lenses of acrylic are employed for their
low (8% per inch thickness) attenuation, and the "slot" window receiver is
internally reflective and vacuumized and/or internally insulated.
The "prism-lens and slot absorber" combination of the present invention is
a linear apparatus, in that the slats and slot receiver-absorber are
elongated for the reception of large quantities of solar light
concentrated upon a restricted focal plane area. As shown, the
prism-lenses and receiver-absorber are disposed in parallel relation, so
that light from the entire area of the slat array is projected through the
slot and onto the focal plane target. In practice, the concentration of
solar light is within a feasible range of use, for example within the
aforesaid range of 500.degree.-700.degree. F., and distributed along the
"slot" window and evenly upon the focal plane and absorber elements,
whereby common commercially available materials are useable in
constructing the receiver and its supporting structure. Only at the focal
plane is any of the apparatus subjected to high heat, and only to that
structure which is in close proximity to the concentrated light.
Solar tracking is to be considered, it being an object of this invention to
simplify tracking with single or a dual axis system responsive to the
azimuth and at least the altitude positions of the sun, regardless of the
latitude and longitude placement of the apparatus. The slat lens array
herein disclosed is particularly adapted to either single or dual axis
tracking, it being a simple matter to track each function of the sun's
position within the resolution desired, as will be described. Accordingly,
there are means that separately determine or detect movement of the sun's
azimuth and/or altitude, and which actuate drive motors that position the
apparatus within the accuracy required for projection of all incoming
solar light through the "slot" window and onto the absorber focal plane
within the receiver.
SUMMARY OF INVENTION
This invention relates to insolation and to the absorption of heat into a
transfer media, by means of optical concentration of heat rays into the
confines of a receiver. The optical system employed herein is
characterized by a multiplicity of transparent slats that are spaced for
ventilation and which are of prismatic lens-shape for refraction and focus
of heat rays upon a focal plane where absorption is to occur. Each
"prism-lens" is of prism-like cross section having a reflective first
surface base that also focuses heat rays passing between spaced slats and
onto the said focal plane where absorption is to occur. The array of slats
is carried by spaced beams cambered so as to accommodate the reflective
light path between prism-lens slats, as they are displaced from a central
projection plane extending to the centerline of the focal plane. The
outermost prism-lens slat is of full isosceles cross section having an
apex and with its base facing said projection plane, while each
progressively inward prism-lens slat is of reduced apex angle and has its
apex truncated more severely and its base diminished, whereby mass is
minimized while retaining sufficient strength. Each prism-lens is of a
cross sectional configuration involving a precise angle, width and base
depth that will focus a full band of heat rays through the "slot" of the
receiver and onto the focal plane of the absorber. The receiver is
characterized by the slot-shaped window through which the heat rays of
solar light are concentrated onto a heat absorption target at the focal
plane. A feature is the narrowness of the "slot" and the openness of the
vacuumized reflective interior of the absorber where heat is taken into a
fluid heat transfer media circulating through the absorber. This
prism-lens array and absorber combination is journaled on a vertical
azimuth axis and at least on a horizontal altitude axis, or compound axes
combining the two, upon which axes or axis it is directed toward the
incoming and parallel sunlight. Tracking is by means of a programmed clock
means or by means of light sensors that detect position of the sun and
actuate motor means to make corrective movements on said vertical and/or
horizontal axes, all in order to maintain the projection plane
coincidental with and parallel to the incoming sunlight, within a
prescribed degree of accuracy or resolution. Any number of these units of
apparatus can be arranged and used together as a multiple array.
The various objects and features of this invention will be fully understood
from the following detailed description of the typical preferred forms and
applications thereof, throughout which description reference is made to
the accompanying drawings, in which:
FIG. 1 is a perspective view of a Solar Concentrating Lens and Receiver
embodying the features of the present invention.
FIG. 2 is an enlarged view of the frame, lens array and receiver, taken as
indicated by line 2--2 on FIG. 1.
FIG. 3 is an enlarged detailed sectional view showing half of the
prism-lens array and taken as indicated by line 3--3 on FIG. 1.
FIG. 4 is an enlarged fragmentary view showing the prism-lens of FIG. 3
having the greatest refraction and reflection angles.
FIG. 5 is an enlarged fragmentary view showing the prism-lens of FIG. 3
having the least refraction and reflection angles.
FIG. 6 is an enlarged sectional view of an intermediate prism-lens and
absorber, showing the focus to a line at the focal plane.
FIG. 7 is a diagramatic view showing the concentration of heat rays onto
the absorber, and the colder rays to the sides thereof.
FIG. 8 is an enlarged detailed sectional view of the absorber.
FIG. 9 is an enlarged detailed plan sectional view through the end mounting
of the receiver-absorber and taken as indicated by line 9--9 on FIG. 1.
FIG. 10 is an enlarged transverse sectional view of the open receiver and
taken as indicated by line 10--10 on FIG. 1, and,
FIG. 11 is a view similar to FIG. 10 showing the receiver closed and with a
modified form of insulation.
PREFERRED EMBODIMENT
Referring now to the drawings, there is a projection plane a that is to be
maintained parallel with the incoming sunlight, within a prescribed degree
of accuracy. In order to do so, there is a vertically disposed azimuth
axis b and at least a horizontally disposed altitude axis c. By setting or
revolving the apparatus about axis b the axis c is brought substantially
or exactly normal to the azimuth position of the sun, and by revolving the
apparatus about axis c the projection plane a is brought into parallel
relation with the incoming light. Accordingly, there is a base B that
revolves on bearings 10 disposed on vertical axis b and carries spaced
trunnions 11 on horizontal axis c. The tracking optical array and
receiver-absorber combination is carried by a frame F journaled on and
within the spaced trunnions 11, a space-frame comprised of spaced side
trusses 12, or the like, between which transparent slats S and a receiver
R extend. The absorber A is centered within the receiver R at the lower
apex of the frame trusses, and the slats S occupy the upper widened
objective end of the frame trusses disposed toward the incoming sunlight.
The frame F is rigid and openly supports the slats S for ventilation, and
all of which is free to revolve on the horizontal altitude axis c.
The objective ends of the spaced trusses 12 are comprised of like or
identical outwardly cambered beams 13 arcuately formed about a center d
substantially below a focal plane P, as shown. In practice, the radius to
d is approximately twice that of the radius to the focal plane P, as
determined by the positioning of adjacent slats S and their revolvement
that places their reflective bases in position to redirect the incoming
sunlight through the intermediate spaces and to the target. The slats S
extend between the beams and are adjustably secured thereto by pivots 14.
The individual slats S are set into proper rotative position parallel with
the centerline of focal plane P as by means of lock nuts 15 at said pivots
14. The frame, beam and slat array are symmetrically disposed about the
projection plane a, the slats S being parallel one with the other and with
the projection plane a.
The slat S array carried by the arcuately cambered beams 13 is
semi-cylindrical, with the individual slats S carried on said mean radius
from a center of arc d. In a reduction to practice of this invention,
there are nineteen slats S at each side of the projection plane a, a total
of thirty eight slats S. The radius to arc center d is approximately 260
inches while the radius from each slat S to the absorber A is optimum.
Assuming the slats S to be flat faced prisms, a sheet of light
substantially equal to the width of the prism will be projected, for
example as shown a width of 3.03 inches. However, it is preferred that the
prisms are cambered to have a lens effect that focuses the incoming
sunlight onto the centerline of the absorber A target. Accordingly, an
aperture 20 is provided to pass these sheets of light from multiple
prism-lenses and into the receiver R, in practice a 50.degree. slot
opening in the receiver body which in a reduction to practice of this
invention is six inches in diameter, and for example with a one inch
absorber widened to one and a quarter inches so as to accommodate stray
light. These dimensional proportions are significant as related to the
slat spacing for ventilation and for reflection off of the bases 17 and
projection of all light onto the focal plane.
Each slat S is of basic prism cross section with its apex 16 disposed
outwardly from the projection plane a, and with its base 17 disposed
inwardly toward the projection plane a. Each slat S is of isosceles cross
section with like or identical sides 18 and 19 extending inwardly from the
apex 16, and the base 17 is disposed at an angle that reflects incoming
parallel sunlight in continuing parallel relation onto the focal plane P.
This slat cross section is prismatic and provides for refraction of light
transmitted through the sides 18 and 19, and provides for reflection of
light striking the base 17.
Each prism cross section of a slat S is precisely formed to have an apex
angle adapted to project a sheet of light totally entering the aperture 20
slot, varying from 45.degree. at the outermost slats S, to 2.7.degree. at
the innermost slats S. The 45.degree. maximum is chosen for reasonable
light transmission efficiency of the prisms, limiting attenuation to
approximately 10%. Also, each slat S is precisely formed to have a
truncated apex adapted to enable strengthening of the slats S by
separating the sides 18 and 19. In practice, the sides 18 and 19 are
separated so that all slats S have approximately the same cross sectional
area, for rigidity as they extend between the beams 13. Accordingly, the
apex truncation and base 17 dimensions vary with the result that the
remaining altitude of the prism slats S, from truncation face to base 17,
varies for example from 2.81 inches at the outermost prism slats S, to
3.03 inches at the innermost prism slats S. These dimensions determine the
spacing of adjacent prism slats S, whereby each reflective base 17 is
entirely exposed to all sunlight passing between adjacent slats.
Structurally, the slats S of prism cross section are made of a plastic
material such as "Lucite" as manufactured by Dupont, a high quality cast
optical acrylic of low attenuation (8% per inch of thickness) having an
index of refraction of 1.49 and a light transmission of 92%. A feature
therefor is the light weight of the plastic having a specific gravity of
1.19, the slats being of slender cross section adapted to remain straight
due to rigidity of the plastic material. Thermal expansion and contraction
has little or no adverse effect on the slats S and their ability to
refract and to reflect light, despite the large objective areas and
intense sunlight that may be involved and concentrated thereby, due to
their separation and individual structural integrity and resistance to
destruction.
In accordance with this invention, the rotated position of each prism slat
S simultaneously adjusts both the refractive and reflective projection of
light through aperture 20. That is, the incoming parallel sunlight rays
are redirected both refractively and reflectively by each prism slat S, to
be projected in substantially parallel relationship. A feature is that the
shadow of light from the apex or the truncated apex end of one prism slat
S is cast to the inwardly turned edge of base 17 of the next adjacent
prism slat S spaced therefrom for ventilation and said reflective passage
of light. It will be observed from FIGS. 3-6 that all parallel incoming
sunlight striking the prism-lens slats S is projected to the target
absorber A, and that the multiplicity of prism-lenses are adjacently
arranged closely but so that one does not shadow the other. Consequently,
all incoming sunlight is projected by refraction and reflection to
concentrate upon the target absorber A at the focal plane P. There is
virtually no waste of incoming light. Therefore, all sunlight entering the
objective array of prism slats S is projected toward the receiver R, said
projected light continuing in substantially parallel rays from each prism
slat S. It will be observed therefore, that the slat openings increase
progressively toward the outward slats S which are wider based and rotated
to a greater reflective angle.
The phenomenon of prismatic refraction produces a spectrum in the form of
an array of components of light separated according to different wave
length, while the phenomenon of lens refraction produces a focused image
and concentration of light at a focal plane. Prismatic separation is the
result of changes in wave length, a divergence of light from the longer
infrared to the shorter ultraviolet rays. Lens focus is the result of
bending the light. In practice and with the reduction to practice
disclosed herein, one or both sides 18 and 19 is cambered as they are
shown and formed to an approximate 190 inch radius so as to have a focal
length of approximately 132 inches with yellow light. Since it is heat
range light which is to be collected by absorption, it is the yellow to
infrared rays which are sought to be captured, and accordingly it is this
range of longer light waves which are focused onto the centerline of the
absorber A by the prism-lens slats S of the present invention. Therefore,
it will be seen firstly, that a multiplicity of sheets of substantially
parallel incoming sunlight are turned by the prismatic refraction of each
slat S to be dominated by the yellow to infrared heat range rays; and
secondly, that this heat range of light rays is inwardly focused by the
convexly cambered sides 18 and 19 to concentrate toward the centerline of
the absorber A at focal plane P.
The phenomenon of dispersion is produced by refraction (not by reflection)
and results in a separation or divergence of light rays from the focus
line which is at the centerline of the focal plane P. Therefore, and
despite the focal length of the convexly cambered sides 18 and 19,
dispersion causes some spreading of the focused light rays. Consequently
with the present invention, there is a concentration of heat rays toward
the centerline of focal plane P, the centerline through which the
projection plane a passes. It is at this centerline of the focal plane P
that the highest heat concentration is developed.
The receiver R and absorber A comprise an insolation device that collects
the heat of absorption into a heat transfer fluid media, by which heat
energy is transported for useful purposes. The array of cambered slats S
results in a narrow concentration of heat range light onto the focal plane
P and embracing the centerline of the absorber A. Accordingly, the
aperture 20 is of sufficient width (see FIG. 10) to pass the convergent
sheets of concentrating light rays from the multiplicity of prism-lenses,
and centered on plane a. As shown, the receiver R involves a closed
chamber C into which the aperture 20 slot opens and in which the
insolation target or absorber A is suspended in a partial vacuum, or
insulated as will be described.
The receiver R is preferably a cylindrical tube 21 of transparent acrylic
plastic, as above referred to, of low heat conductivity closed at opposite
ends by insulating walls 22 that are secured to the trusses 12 of the
frame F. As shown, a vacuum pump (not shown) draws through line 23 from
the interior of the closed chamber C, a vacuum of, for example, 1/1000
atmosphere. The center of tube 21 is at the focal plane P and the wall of
the tube is clear and transparent. In the reduction to practice disclosed
herein, the objective angle of concentration is 50.degree., in which case
a window or slot of commensurate angular opening is left remaining through
the wall of the tube, centered on the projection plane a, while the
remaining interior of the tube wall is interiorly reflective. As shown,
the interior of tube 21 is lined with a reflective shield or coating 24.
The insolation target is the absorber A suspended in the receiver at the
center thereof and provided to receive the heat of absorption and to
conduct it into a heat transfer media such as for example a liquid so as
to achieve higher temperature without evaporating. The absorber A is
partially surrounded and embraced by a shield 25, and it is a flat plate
or band substantially coextensive in width with the effective
concentration of heat rays at the focal plane P. As shown, the absorber A
is elongate and coextensive with the receiver tube 21, and its widened
face 32 disposed diammetrically within the tube and coincidental with the
focal plane P centered on the projection plane a. In practice, the band
width of the absorber A is substantially narrower than the aperture 20
slot.
The shield 25 is a partial cylinder with a reflective inner surface secured
to the end walls 22 of the receiver and disposed concentric with the tube
wall thereof. The shield 25 is open sided with an aperture opening of
50.degree. to pass all incoming sunlight that concentrates through the
aperture 20 slot. The interior of shield 25 is approximately twice the
diameter as the absorber width and/or aperture opening therethrough, and
its interior is highly reflective. As shown, the shield 25 is carried by a
member 26 formed of structural insulation.
In accordance with this invention, the absorber A is a laminate structure
channeled for the transport of fluid media therethrough. Accordingly, the
absorber A is comprised of a target lamina 30 and a support lamina 31,
bonded together as by furnace brazing. The target lamina 30 is formed of a
material having high heat conductive properties such as copper and
externally coated with a black chrome surface 32 or the like. The support
lamina 31 is formed of a material having lower heat conductive properties
such as a stainless steel which has strength for support. The lamina 30 is
longitudinally grooved to provide a plurality of fluid channels closed by
the lamina 31 bonded thereto, lamina 31 having depending flanges for beam
strength. As shown in FIG. 8, the laminae 30-31 have planar faces that are
brought permanently together. The fluid media is routed into the marginal
channels 33 of the absorber to emanate from a central channel 34, for the
progressive increase of heat absorption. Insulation is by means of the
vacuum drawn from chamber C through line 23. In the second embodiment of
FIG. 11, insulation is by means of a high temperature window tube 35
surrounding the shield 25' and by an insulation carrier 26' that occupies
the annulus between the shield 25' and tube 21 wall, the aperture 20 area
remaining open through both the tube 21 and tube 35 and between the
flanges 28'. In practice, the window tube 35 is made of a heat resistant
glass such as "Pyrex" or the like. The chamber C within tube 35 may or may
not be vacuumized.
It will be observed that the shield has marginal flanges 28 in the FIG. 10
embodiment, which define the slot 20 as it opens between the target
absorber A and tube 21 wall of the receiver R. In the FIG. 11 embodiment
the reflective layer 24' has marginal flanges 28' which define the said
slot 20. The flanges 28-28' too are highly reflective at their inner faces
to collect and redirect stray light. There is a phenomenon knwon as
"Sky-Shine", or the presence of scattered light as will occur on hazy days
when particles in the atmosphere causes sunlight to diffuse in many
direction. It is known that this scattered light can be collected and/or
accumulated even though it is not direct in the sense of emanating in
parallel rays of sunlight. Accordingly, and referring particularly to
FIGS. 10 and 11 of the drawings, this invention provides reflective
shutters 50 that close as shown in FIG. 11 to protect the absorber A when
it is not conditioned to receive high heat, and that opens as shown in
FIG. 10 to collect scattered "Sky-Shine". As shown, the shutters 50 are
flat internally reflective panels pivoted outside the convergence of light
concentration, to be planar with the reflective flanges at a 50.degree.
included angle as shown. The shutters 50 are longitudinally coextensive
with the receiver slot 20, and consequently stray light is concentrated
into the receiver R and onto the absorber A.
The lens array and solar absorber hereinabove described is adaptable to
either single or dual axis tracking. When geographic location does not
create too great a variation in azimuth position of the sun, single axis
altitude tracking is in order. However, when azimuth position changes too
greatly, or when greatest efficiency is required, then dual axis azimuth
and altitude tracking is in order. As shown, the axis to be motivated is
controlled by a programmed drive or clock means, or by sun position
sensors, whereby tracking is accomplished. As shown, there is a gear motor
36 that revolves the base B on the vertical azimuth axis b, and there is a
gear motor 37 that revolves the frame F on the horizontal altitude axis c.
For programmed tracking, a programming clock means is supplied with azimush
and/or altitude information on sun positions for the instants in time
throughout each successive day, and this clock means governs the rotative
position or positions of said axes. For position sensing tracking, a sun
position sensor is provided for the tracking axis to be controlled. As
shown, a tracking tube 38 is aligned normal to the axis c so as to detect
azimuth position of the sun, and a tracking tube 38' is aligned with the
projection axis a so as to detect altitude position of the sun. The
tracking tubes 38 and 38' are alike and each is elongated with a slotted
aperture 39 at its objective end, and with spaced light sensor means such
as photo cells 40 and 41 at its remote base end. The slotted aperture is
parallel with the axis to be controlled and the sensor cells 40 and 41 are
separated by a partition 42 and actuate the gear motors 36 or 37 as the
case may be, to operate forwardly and reversely. A shaft of light enters
through the slotted aperture 39 to play on either sensor 40 or 41, with
accuracy predetermined by narrowness of the said aperture and its distance
from the controlling sensor cells. In practice, search sensor cells are
located near the aperture for initial tracking, to be switched off when
normal tracking is in process.
From the foregoing it will be seen that all incoming sunlight is
effectively utilized, by both refraction and reflection to enter through a
narrow slot into a vacuumized chamber where heat of absorption is
collected into a fluid transfer media for transmission to a useful
purpose. The capture of heat energy is efficiently conserved within the
insulated confines of the internally reflective receiver, re-radiation
being restricted by the narrow slot aperture through which all incoming
sunlight enters for concentration along the projection plane and at the
focal plane of the multiple prism-lens array.
Having described only the typical preferred forms and applications of our
invention, we do not wish to be limited or restricted to the specific
details herein set forth, but wish to reserve to ourselves any
modifications or variations that may appear to those skilled in the art as
set forth within the limits of the following claims.
* * * * *
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