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Claims  |
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What is claimed:
1. A solar energy collector apparatus comprising an outer hollow, elongated
tubular member of transparent glass, closed at its one end and open at its
other end, a hollow, elongated tubular glass absorber member defining a
glass wall of lesser O.D. than the I.D. of said outer member and closed at
its one end and open at its other end, the absorber member having its
exterior surface comprised of an energy absorbing coating applied thereon
over a substantial portion of its axial length, said coating having high
absorption and low emission properties, said absorber member being
inserted within said outer member, resilient end support means engaging
said closed end of the absorber member supporting it firmly in spaced
relation to the interior surface of said outer member near the closed end
of the latter and providing for expansion and contraction of the absorber
member, an annular end portion of the glass at the open end of said
absorber member being fused annularly onto the glass wall of the outer
member, thereby sealing it to said outer member adjacent its other open
end and closing an annular space therebetween, said space being evacuated,
a heat exchange member communicating with the hollow interior of said
absorber member, a fluid media supply means, and means connecting the
supply means to the heat exchange member, whereby the fluid media absorbs
the energy exchanged from the absorber member.
2. The solar energy collector apparatus of claim 1, wherein the annular end
portion of glass adjacent the open end of said tubular absorber member is
flared outwardly and fused integrally with the glass at the open end of
said outer glass member.
3. The solar energy collector apparatus of claim 1, wherein the energy
absorbing surface coating on the absorber member comprises a wave length
selective coating having an absorptance of 0.80 or greater and an
emittance of 0.10 or less.
4. The solar energy collector apparatus of claim 3, wherein said wave
length selective coating comprises a sub-coating layer of a metal selected
from a group consisting of aluminum, silver, copper and gold and an
over-layer of a metallic compound selected from a group consisting of
oxides and sulphides of chrome, nickel and copper including combinations
thereof.
5. The solar energy apparatus of claim 1, wherein said outer member and
said fluid handling member are each constructed of drawn, cylindrical
glass tubing and said absorber member is constructed of cylindrical glass
tubing having an opaque coating of said energy absorbing compound
encircling the exterior surface thereof and said coating is contained
within said evacuated space.
6. The solar energy collector apparatus of claim 1, wherein the resilient
end support means comprises a coil spring axially compressed between said
closed end of the absorber member and the closed end of the outer member.
7. A tubular solar energy collector comprised of a circumferentially
transparent glass outer tube having a closed end and an open end and,
interiorly of said outer tube, a hollow elongated glass tubular absorber
member of a lesser O.D. than the I.D. of said outer tube and having a
closed end and an open end and including a solar energy absorbing surface
disposed between said ends thereof, a glass-to-glass fusion seal closing
the opening between said absorber member and outer tube adjacent the open
end of the outer tube to thus provide a closed space therebetween, said
space being evacuated, said absorbing surface comprising an opaque wave
length selective coating encircling the external peripheral glass surface
of said tubular absorber member, said coating having an absorptance of
0.80 or more and an emittance of 0.1 or less.
8. The tubular solar collector of claim 7, wherein the open end of said
tubular glass absorber member includes an outwardly flared end portion,
said flared end portion being fused onto the glass wall of said outer tube
thereby sealing the space between the outer tube and said interior tubular
absorber member.
9. The tubular solar collector of claim 7, wherein said wave length
selective coating comprises a wave length selective coating having an
absorptance of 0.80 or greater and an emittance of 0.10 or less.
10. The tubular solar collector of claim 7, including means for supplying a
working fluid to the absorber member in heat exchange relation therewith
and extracting heat therefrom.
11. The solar energy collector of claim 10, wherein said means for
supplying working fluid comprises a manifold sealingly connected to the
open end of the outer tube for receiving heated working fluid from the
absorber tube, a source of the working fluid connected to the manifold, a
fluid circulation tube communicating with said manifold and the working
fluid therein and extending interiorly of said absorber member to a
location spaced from and adjacent to its closed end.
12. The solar energy collector of claim 11, wherein said fluid circulation
tube is comprised of glass.
13. A solar energy collector apparatus comprising a first elongated, hollow
transparent cylindrical glass tube having its one end closed and the other
end open, a second elongated, hollow transparent cylindrical glass tube
having its one end closed and the other end open and disposed within said
first tube, the glass composition of both said glass tubes being
substantially the same, a surface coating of energy absorbing material on
the peripheral exterior surface area of said second tube, said coating
having high absorptance and low emittance, means on the closed end of said
second tube holding the second tube in spaced relationship to the first
tube defining a space therebetween, means sealing the wall portion of the
open end of the second tube onto the wall of the first tube, said means
comprising an encircling, annular fusion of the glass at said open end of
the second tube with the first tube enclosing a space therebetween, said
space being evacuated, a source of working fluid, means for introducing
working fluid into heat exchange relationship with the second tube, and
means for conducting solar energy laden working fluid away from the
collector apparatus.
14. The solar energy collector apparatus of claim 13, wherein the first and
second glass tubes are formed from drawn glass tubing and the open end
portion of the second tube includes an outwardly annular portion, said
flared portion being fused onto the wall of the first tube adjacent the
open end thereof. |
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Claims |
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Description |
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The present invention relates to solar energy collectors. More
specifically, the invention provides a relatively inexpensive and
efficient unit for installation as a module or unit in a solar energy
converter system.
SUMMARY OF THE INVENTION
The basic components of the energy collector unit for the system are made
of glass of known tubular manufacture such as are prevalent today in the
manufacture of glass tubing products, e.g. process glass pipe, or the
like.
The tubular glass solar energy collectors are assembled onto a manifold
such that the tubular collectors are detachably connected into a manifold.
The manifold may be constructed for disposition of the collectors on
either side thereof so as to extend laterally in rows along the manifold
and provide an energy collecting system connected for either cooling or
heating uses.
OBJECTS OF THE INVENTION
One of the important objects of the present invention is to provide a
collector unit of low cost of manufacture and of operation. The collector
unit may be mass produced of relatively inexpensive raw materials, the
bulk of which is glass, and may be maintained in use or replaced easily.
Another important feature of the invention is the construction of the
collector wherein the components comprised of three concentric tubes are
made of glass. The two outermost tubes are constructed from glass tubing
to resemble oversized test tubes in that their one end is closed. The
outer tube is sealed to the intermediate inner tube and the space
therebetween evacuated to a practical and efficient degree of vacuum to
prevent heat loss through the space by convection and conduction heat
loss. The intermediate inner tube is coated with an energy absorbing
coating of high absorptance and low emittance. The third tube is placed
inside the intermediate tube and is used to carry the fluid medium to the
interior, closed end of the latter. The parts thus described, aside from
the coatings, are of the same or similar composition of glass. The thermal
expansion characteristics are similar and allow a glass-to-glass flame
seal rather than a glass-to-metal gradient seal used in this type of
collector heretofore, thereby avoiding failure from thermal expansion
differences during operation. Additionally, the glass parts may be sealed
one to the other more readily and with less cost in manufacture.
A further object of the invention is to provide a manifold for the fluid
medium flow into and out of a plurality of the collector units connected
thereto, and the collector units are provided with a quick disconnect and
O-ring seal in a socket of the manifold for each collector unit.
Another object of the invention is to provide a spring support means
connected to the interior end of the coated, intermediate absorber tube
holding that end of the tube in concentric position in the outer tube, the
other end of the absorber tube being sealed to the wall of the outer tube
for support.
Other objects and advantages will become apparent from the following
description in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view showing the invention in use on the roof slope
of a dwelling.
FIG. 2 is a side view, partly broken away and in section, of collector unit
of the invention.
FIG. 3 is an exploded, perspective view, partly broken away and in section,
showing a solar energy converter system module of the double manifold
embodiment, wherein collector units extend on either side of the manifold.
FIG. 4 is a sectional plan view of a portion of the manifold of FIG. 3.
FIG. 5 is a perspective view of the end cap providing an inner end support
means for the coated absorber tube of the collector inside the outer
jacket tube.
FIG. 6 is a staggered sectional end view of the collector taken along line
6--6 on FIG. 2. FIG. 7 is a side elevational view, partly broken away and
in section, of a second embodiment of collector unit of the invention.
FIG. 8 is a fragmentary, enlarged sectional view of the fusion assembly of
the glass absorber tube and the glass outer tube of the collector unit of
FIG. 7.
DESCRIPTION
Shown on FIG. 1 is a typical in-use setting for the invention. The dwelling
10, such as a residence, has its roof section 11 located nearest the sun
or most accessible to the sun, provided with plural modules 12 of the
solar energy converter of the invention. The area selected for coverage by
modules 12 may be left to the skill of the engineer and architect
providing for the heating or cooling for the dwelling.
The Manifold
The module of the solar energy converter is shown in detail on FIG. 3.
Module 12 which appears in part on the exploded view, comprises a central
longitudinal manifold section 13 that extends down the roof section (FIG.
1). Extending outwardly from either side of the manifold 13 are plural
collector units 14, to be presently described. The collectors 14 are of a
plug-in type of connection into the side ports 15 spaced along the
opposite vertical side walls 16 and 17 of manifold 13. Internally of
manifold 13 are longitudinal passageways 18 and 19 running along the ports
15 on either side of the manifold. Sandwiched between passageways 18 and
19 is a central passageway 20 defined by the longitudinal interior
vertical walls 21 and 22. Along walls 21 and 22 there are spaced apart
ports 23. The ports 15 and 23 are matched as sets on the same central
axis, i.e., the ports are coaxial.
The manifold 13 connects into a fluid handling system illustrated by the
duct 24 having an upper conduit passage 25 and a lower conduit passage 26.
The duct 24 extends between the heating or cooling system (labelled "Fluid
Heat Exchanger" on FIG. 3) and the solar converter module 12. The passage
25 carries the relatively cool fluid medium, such as water, air or the
like, and inroduces it through the matching aperture connection 39 in the
vertical wall 24a of duct 24 and aperture 27 in the vertical end wall 28
of manifold 13. The aperture 27 connects into the central passageway 20 of
manifold 13. The duct 24 and manifold 13 are connected and sealed together
by the gasketed facing 29 held by cap screws 30 threaded into end wall 28
at 31. Gasket 29 may be any suitable compressible gasket material that
will withstand elevated temperature service. Matching lower apertures 32
and 33 in wall 24a and 34 and 35 in wall 28 connect the respective
passages 18 and 19 with the duct passage 26 for carrying the heated fluid
medium coming from the collectors 14.
Manifold 13 is enclosed by top and bottom walls 36 and 37, respectively,
and at its outer end by vertical wall 38.
The Collector Unit -- First Embodiment
The collectors 14 shown on FIGS. 2 and 3 are all constructed alike, and
each comprises an outer glass tube 40 that is of convenient length, say
from 4 to 7 feet and of standard diameter, e.g. 2 inches O.D. A lower
mirrored surface 45 may be employed to reflect radiant energy onto a
portion of the absorber tube 41 of the collector.
The interior tube 41 is made of glass and is of somewhat lesser diameter
and of slightly greater length. Tube 41 has its exterior surface precoated
with an energy absorbing coating 42 having a high absorptance and low
emittance. Examples of such wave length selective coatings are metallic
undercoatings such as aluminum or silver deposited upon the glass surface,
and a semi-conductor type coating is next deposited over the metallic
surface coating to provide the wave length sensitivity desired. A high
performance wave length selective coating is preferred having 0.8 or
greater absorptance and 0.1 or lower infra red emittance.
Inside tube 41 there is a fluid delivery glass tube 43 for conveying
relatively cool fluid medium into the collector interiorly of tube 41 and
adjacent the closed end wall 41a thereof. The inner end 43a of delivery
tube 43 is open (FIG. 2).
In assembly, the absorbing tube 41 already coated on the exterior with the
wave length selective coating 42, is further provided with the snap-on end
support cap 46 (FIG. 5) which provides inner end support means for tube 41
in tube 40. Cap 46 comprises a semispherical shell and multiple (either 3
or 4) legs 47. The cap 46 is made of metal or plastic having some
resiliency to maintain its force fit on the inner end of tube 41. Tube 41
is then inserted into the outer tube 40 and in this first embodiment of
the invention is fastened to outer tube 40 by fusing its open end onto
tube 41 at the juncture 40a (FIG. 2). Thereafter, a vacuum is pulled
through the opposite end of tube 40 at a tubulation and sealed off at the
tip 48 in the manner known to those skilled in the art, the resultant
sealed space 49 between the outer tube 40 and absorber tube 41 being
highly evacuated; viz on the order of 10.sup.-4 torr of vacuum. Next the
delivery tube is inserted interiorly of the absorber tube 41. Each of the
collector units 14 is detachably assembled into the manifold 13 as
follows. The free end 43b of the delivery tube 43 is approximately the
same O.D. as the diameter of the ports 23 in the interior walls 20 and 21
of the manifold. A rubber O-ring 50 is provided on free end 43b of the
delivery tube to seal the latter in port 23. Similarly, free end 41b of
the absorber tube is approximately the same O.D. as the port 15 in either
of vertical side walls 16 or 17. A rubber O-ring 51 is provided on free
end 41b of the absorber tube to seal it in port 15. The ports 15 and 23
are each provided with recess grooves 51a and 50a respectively, to receive
the gasket O-rings 51 and 50 therein.
The Collector Unit -- Second Embodiment
The collector construction shown on FIGS. 7 and 8 has similar parts
labelled with corresponding numerals marked by a prime designation.
The collector 14' is comprised of a glass outer tube 40' that is
transparent or clear and is closed at its one outer end in a sealed
tubulation 48'. The opposite end of tube 40' is open. The interior tube
41' is made of glass tubing of somewhat lesser diameter and length. The
interior glass tube 41' has its exterior surface precoated over
substantially its length and periphery with the high absorptance and low
emittance wave length selective coating 42' as described earlier herein
under the first embodiment. Before the coating 42' is applied, preferably,
the open end of glass tube 41' is worked to an outwardly flared end
opening of the contour of the flared end 60 shown on FIGS. 7 and 8. The
coating 42' is applied on the tube adjacent the flared end 60 to and
inclusive of the closed end of tube 41'. Next, tube 41' is inserted into
glass outer tube 40', a simple coil spring 61 being first assembled to fit
on the closed end of tube 41' and bear against the closed end on the
inside of outer tube 40'. At this stage of assembly, the tubulation at 48'
is still open. With the tubes 40', 41' in place, as shown on FIG. 7, and
spring 61 being somewhat compressed, the flared end 60 of tube 41' and the
open end portion of tube 40' are heated and the glass fused together to
form the integral end connection of the two tubes 40', 41', such as shown
on FIG. 8. Thereafter, a vacuum is pulled through the opposite end
tubulation at 48' of the outer tube 40' and sealed off at the tip 48'
shown, which seals the space 49' between the outer tube 40' and the inner
absorber tube 41' at a vacuum, preferably on the order of 10.sup.-4 torr
or greater of vacuum. The coating 42' is thus contained within the vacuum
of space 49'. A delivery tube 43' is inserted through a wall member 62 and
annular rubber grommet 63 in a port 15' or 23' on one side or the other of
the manifold 13, as described earlier herein. A rubber O-ring 51' is
seated in a groove 51a'of the port 15' and compressed against the outer
wall surface of tube 40' near the open end of the collector. The O-ring
51' forms the primary seal for the collector 14' in the manifold port.
Manifold 13 includes a layer of foamed insulation 64 around its exterior,
exposed surfaces, and at locations corresponding to the collector ports in
the manifold, the insulation layer includes formed ports 65 registering
with the manifold ports. A thin washer-like seal 66 of flexible material
is imbedded in the insulation within the bore of each of the ports 65
which annularly engage the periphery of the tube 40' thereby providing an
outer seal in the ports.
The outer tube 40' is made of high transmittance and preferably low iron
transparent glass. The inner absorber tube 41' is preferably of
substantially the same glass composition as tube 40' for ease in the
joining process and to reduce the residual stress at the fusion seal
between the outer and inner tubes near their open ends.
Regarding the wave length selective coating layer 42' on glass tube 41',
the coating comprises a substance having 0.80 or greater absorptance and a
sub-coat having 0.1 or less emittance. For high absorptance as indicated,
metallic compounds such as oxides or sulphides of chrome, nickel, copper
or the like can be used with success. Sometimes a combination of metal and
its compounds is best for the solar energy absorption. For low emittance
as indicated, aluminum, silver, copper and gold are preferred as the
sub-coat, the high absorption coating substances being superimposed
thereover.
Any method of deposition of the coating substances selected must be capable
of applying a controllable think film. Such methods used with success are
vacuum deposition, chemical vapor deposition, ion-plating and sputtering.
In the invention, energy absorbing coatings not suitable in other types of
collectors, such as flat plate collectors, may now be used because the
coating is protected in the space 49' between the tubes at hard vacuum
environment. Chemical attack by air and moisture or lack of bonding
integrality are alleviated and no longer detrimental factors in the
tubular solar energy collector herein disclosed.
The spacing means used between the closed ends of the inner and outer tubes
41', 40' of the collector can be of any design or material. The design
criterion is that it must provide a firm support of the inner tube end to
minimize the stress created at the opposite fused ends, or open ends of
the tubes. It must allow the inner tube to expand or shrink according to
its temperature without developing undue stress at the mentioned fused
joint. Also, it must have preferably a minimum contact surface between the
tubes and the spacing means to minimize heat loss by conduction, and it
must also serve as a support during the sealing operation. As is disclosed
herein, the spacing means may take the form of the snap-on clip 46 (FIG.
5) or the coil spring 61 (FIG. 7).
Because the spacer means is in the space to be evacuated to a hard vacuum,
the material thereof used should not release gases after bake-out and
tip-off of the outer tube 40 or 40' in the evacuating process. Also, the
material of the spacer must be free of oily substance and organic bonding
material, which would be be eliminated at a bake-out temperature for
evacuation. Stainless steel properly cleaned is the preferred material.
Operation of the Collector Module
Utilizing the assembly shown on FIG. 3, and described earlier herein, a
fluid medium, for example air, is pumped in duct 25 into central passage
20 of the manifold. The free ends 43b of the several collectors 14
communicate with passage 20 and are sealed therein so that the air flows
lengthwise of the delivery tube 43 and exits at inner end 43a. Solar rays
penetrate the upper glass of tube 40 and energy therefrom is absorbed by
coating 42 of the absorber tube 41. The air circulated on the interior of
tube 41 traverses the passage defined by helical baffle 44 and heat
exchange therewith increases the temperature of the air as it travels
toward the free end 41b of tube 41.
When heated air reaches the free end 41b of the tube connected thereat into
either passageway 18 or 19, as the case may be, the heated fluid media
flows into the lower duct 26 and is utilized to either heat or cool
dwelling 10, or service hot water heating, or both.
One of the significant advantages of the system is experienced in the
collector units 14 or 14' of the invention. Should any one of the
collectors be damaged, break or malfunction, a replacement may be readily
inserted and the defective unit removed, thereby maintaining the
efficiency of the system.
The glass tubes of the unit are fabricated from known and standard glass
shapes of either a soda-lime glass composition or a borosilicate glass
composition. Both glasses are relatively inexpensive. The system and
modules thereof may be assembled on the site of installation and need not
be prefabricated at the factory and delivered to the site. The solar
energy collector of this invention is simple to manufacture and assemble.
Furthermore, it is lightweight; therefore, there is no need to further
structure or reinforce the roof of the building where it is installed.
In use of the invention, the working fluid is deliverable from the
collectors at a temperature in excess of 250.degree. F. The energy
absorbing coating 42 or 42' is totally protected and will last the
lifetime of usage of the collector unit.
The module concept illustrated herein includes the preferred embodiment
whereby collectors extend on both sides of the manifold -- a "double
acting" system. It is also within the scope of the invention to fabricate
a "single acting" system wherein collectors extend only along the one side
of the manifold. This may have some specialized uses, but, as stated, the
double acting system is the preferred embodiment.
Other and further modifications may be resorted to without departing from
the spirit and scope of the appended claims.
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