BACKGROUND OF THE INVENTIONIt is generally appreciated that one of the many known technologies for generating electrical power involves the harvesting of solar radiation and its conversion into direct current (DC) electricity. Solar power generation has already proven to be a very effective and “environmentally friendly” energy option, and further advances related to this technology continue to increase the appeal of such power generation systems. In addition to achieving a design that is efficient in both performance and size, it is also desirable to provide power units and corresponding solar systems that are characterized by reduced cost and increased levels of mechanical robustness.
Solar concentrators are solar energy generators which increase the efficiency of conversion of solar energy to DC electricity. Solar concentrators which are known in the art utilize parabolic mirrors and Fresnel lenses for focusing the incoming solar energy, and heliostats for tracking the sun's movements in order to maximize light exposure. A new type of solar concentrator, disclosed in U.S. patent application Ser. No. 11/138,666, entitled, “Concentrator Solar Photovoltaic Array with Compact Tailored Imaging Power Units” utilizes a front panel for allowing solar energy to enter the assembly, with a primary mirror and a secondary mirror to reflect and focus solar energy onto a solar cell. A back panel and housing enclose the assembly and provide structural integrity. The surface area of the solar cell in such a system is much smaller than what is required for non-concentrating systems, for example less than 1% of the entry window surface area. Such a system has a high efficiency in converting solar energy to electricity due to the focused intensity of sunlight, and also reduces cost due to the decreased amount of costly photovoltaic cells required. Because the receiving area of the solar cell is so small relative to that of the power unit, the ability of the mirrors to accurately focus the sun's rays onto the solar cell is important to achieving the desired efficiency of such a solar concentrating system.
In this type of solar concentrator panel, one of the key factors in mirror alignment is the process by which a mirror is adhered to the front or back panel. Uncontrolled adhesive application may result in variations in adhesive thickness across the bonding area of the mirror, which in turn may affect the alignment of the mirror as well as the bond strength which is important for withstanding high temperature conditions in the solar power assembly. In another instance, the proper amount of adhesive may be applied, but pressing the mirror and panel together in an uncontrolled manner may cause the adhesive to be exuded beyond the desired bond area and into the clear aperture of the system. Difficulty in attaining consistent adhesive application can decrease manufacturability and thus the commercial feasibility of such a design.
One solution to this problem of mirror alignment and attachment is using spacers to set the distance between the mirror and panel to which it is to be bonded. U.S. Pat. No. 5,433,911 entitled “Precisely Aligning and Bonding a Glass Cover Plate Over an Image Sensor” discloses an electronics package which includes a spacer plate, a glass cover plate, an image sensor, and a carrier. In order to achieve the tight tolerances for spacing and parallelism which are required to align the various planar components in this assembly, precision ground and lapped spacers are used. While the spacers result in the desired alignment and spacing between the plates and image sensor, the precision to which they must be made and the accuracy with which they are mounted increase the labor and cost of the assembly. The fact that the spacers are separate components also adds complexity to the manufacturing process.
Spacer particles are another approach to setting uniform distances between surfaces. U.S. Pat. No. 7,102,602 entitled “Doubly Curved Optical Device for Eyewear and Method for Making the Same” discloses a pair of substrates sealed together by a fluid material with spacers disbursed therein. The substrates thus have a uniform controlled distance there between due to the presence of the spacers. The spacers may be placed between the substrates prior to application of the fluid, or they may be mixed into the fluid material first and then applied to the unopposed substrates. While spacer particles are useful in setting the gap of a critical dimension, an assembly with more than one critical dimension would require specifically-sized spacer particles for each application. Such a situation raises the likelihood for potential manufacturing errors should one spacer size be mistakenly used in place of another size. Furthermore, each batch of adhesive would require verification of the proper ball diameter, and the step of mixing spacers into the fluid or adhesive adds labor to the manufacturing process.
Thus it is desirable to facilitate reliable alignment and attachment of the mirrors in a solar energy system in a manner which enhances manufacturability and therefore reduces overall cost and improves mechanical robustness.
SUMMARY OF THE INVENTIONThe present invention is a solar energy system, including a front panel and at least one mirror. In the preferred embodiment, three or more nubs are an integral part of the mounting surface of the mirror. When the system is assembled, these nubs are configured between the panel and the mirror and provide a substantially uniform gap for an adhesive. The mirror is secured to the panel by the adhesive. Thus, the nubs assist with desired attachment and alignment of the mirror to the panel in the solar energy system.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 provides a perspective illustration of an exemplary embodiment of the solar power unit;
FIG. 2 shows a cross-sectional view of the assembly ofFIG. 1, with additional housing components;
FIG. 3 illustrates a side view of a secondary mirror with nubs mounted onto a front panel;
FIG. 4 provides a plan view of one embodiment of nubs on a secondary mirror;
FIG. 5A gives a perspective view of an alternative embodiment of a secondary mirror;
FIG. 5B is a cross-sectional view of the embodiment ofFIG. 5A;
FIG. 6 shows a perspective view of an exemplary primary mirror with nubs on its perimeter;
FIG. 7 shows an exploded perspective view of an embodiment of the assembly process for aligning and attaching a secondary mirror onto a front panel; and
FIG. 8 is a simplified flowchart illustrating basic steps in the fabrication process.
DETAILED DESCRIPTION OF THE EMBODIMENTSReference now will be made in detail to embodiments of the disclosed invention, one or more examples of which are illustrated in the accompanying drawings. Each example is provided by way of explanation of the present technology, not limitation of the present technology. In fact, it will be apparent to those skilled in the art that modifications and variations can be made in the present technology without departing from the spirit and scope thereof. For instance, features illustrated or described as part of one embodiment may be used on another embodiment to yield a still further embodiment. Thus, it is intended that the present subject matter covers such modifications and variations as come within the scope of the appended claims and their equivalents.
The alignment and attachment means described in this disclosure are based on a solar power unit design incorporating optically aligned primary and secondary mirrors. The solar power unit design is described in detail in related, co-pending patent applications as follows: (1) “Concentrator Solar Photovoltaic Array with Compact Tailored Imaging Power Units;” Ser. No. 11/138,666; filed May 26, 2005; and (2) “Optical System Using Tailored Imaging Designs;” Ser. No. 11/351,314; filed Feb. 9, 2006, which claims priority from U.S. provisional patent application 60/651,856 filed Feb. 10, 2005; all of which are hereby incorporated by reference as set forth in full in this application for all purposes.
Note that variations on the design described in the priority applications may be achieved by modifing specific steps and/or items described herein while still remaining within the scope of the invention as claimed.
With reference toFIG. 1, a simplified perspective view of an exemplarysolar power unit100 is shown. The main optical elements of thepower unit100 are aprotective front panel110, aprimary mirror120, asecondary mirror130, and areceiver assembly140. Note that for commercial application, thesingle power unit100 would typically be replicated to form an array of adjoining power units as part of a complete solar panel.Protective front panel110 is a substantially planar surface, such as a window or other transparent covering, which provides structural integrity for a power unit and protection for other components thereof In a preferred embodiment,front panel110 is composed of glass; however, any type of transparent or transmissive planar sheet, such as polycarbonate, may be suitable for use in the solar power unit. Sunlight enters thesolar unit100 throughfront panel110 and reflects off ofprimary mirror120 tosecondary mirror130, where it is further reflected and focused ontoreceiver assembly140. In the preferred embodiment,receiver assembly140 houses an optical rod and a photovoltaic cell where the intensified sunlight is converted into electrical energy.
In reference still toFIG. 1,primary mirror120 andsecondary mirror130 are substantially co-planar, at least a portion of both mirrors being in contact withfront panel110. In the depicted configuration,primary mirror120 is generally circular such that theentire perimeter160 ofprimary mirror120 is contact withfront panel110.Primary mirror120 is preferably a second surface mirror using, for example, silver, and slump-formed from soda-lime glass. In one exemplary embodiment,primary mirror120 may have a diameter of approximately 280 mm and a depth of approximately 70 mm.Secondary mirror130 is also generally circular, and is typically a first surface mirror using silver and a passivation layer formed on a substrate of soda-lime glass. In a preferred embodiment,secondary mirror130 may have a diameter of approximately 50 mm.Nubs150, to be described in further detail in reference to later figures, are present on the surface ofsecondary mirror130 which is facingpanel110.
Turning now toFIG. 2, a cross-sectional view of asolar power unit200 is shown. The same elements given inFIG. 1 of afront panel210,primary mirror220,secondary mirror230 withnubs250, andreceiver assembly240 are shown. In the view provided inFIG. 2, however, the additional components of ahousing260 andback panel270 are illustrated in basic form.Housing260 may be built from more than one piece of material, such as but not limited to stamped metal or polyethylene terephthalate (PET) and is designed to accommodate the total number of power units provided in a given solar energy system. The housing contains alip262 that allows thefront panel210 to be mounted, preferably with a rubber gasket (not shown) to seal the edges ofpanel210.Back panel270, which may also be referred to as a base plate, serves as a heat dissipation element for the solar unit and may be formed of phosphor-bronze or an aluminum alloy.Housing260 andback panel270 may be secured to the solar energy system by bolts, screws, or similar means (not shown) well-known in the art.
FIG. 3 provides a closer view ofsecondary mirror330 andfront panel310. Nubs350 are shown as projections from mountingsurface340 ofsecondary mirror330.Nubs350 can be separate pieces from thesecondary mirror330, or are preferably integrally fabricated as part ofsecondary mirror330. By havingnubs350 integral tosecondary mirror330, any manufacturing tolerances resulting from either fabricating separate nub components or adheringnubs350 to surface340 are eliminated. Integral nubs fabrication could entail thenubs350 being molded into the shape of themirror330 during the mirror pressing process. Alternatively,nubs350 could be separate components that are insert-molded into the mirror during the pressing process. The height ofnubs350 are substantially equal, which advantageously sets a substantially uniform gap between mountingsurface340 ofsecondary mirror330, andbottom surface360 offront panel310. This uniform gap thereby substantially alignssecondary mirror330 in parallel tofront panel310. In a typical embodiment, the distance between mountingsurface340 ofsecondary mirror330 andback surface360 of thefront panel310 is 50 microns to 2.0 mm. Secondary mirror is secured tofront panel310 by adhesive320, which fills the space betweensurfaces340 and360. In a preferred embodiment, silicone adhesive is used; however, any adhesive (epoxies, RTV, acrylics, etc.) which is appropriate for the substrates and operating conditions of this assembly may be utilized.
FIG. 4 next illustrates a plan view of the mounting surface ofsecondary mirror410. In this embodiment, threenubs420 are shown to be equally distributed near thecircumference430 of themirror410. The presence of threenubs420 establishes the planar stability ofsecondary mirror410. Alternatively, more than three nubs may be used for aiding the visual inspection that nubs420 are contacting the front panel (surface360 ofFIG. 3), or for mechanical redundancy should any of thenubs410 be damaged during the manufacturing process. While the placement ofnubs410 nearcircumference430 as shown is desirable for increasing planar stability, the nubs may be placed in other configurations away from the circumference. For example, a nub positioned in the center of thesecondary mirror410 could be used to help center the secondary mirror onto the front panel. In another instance, the placement of nubs can assist in outlining the zones in which adhesive is to be dispensed.
Still referring toFIG. 4,nubs420 are shown to be circular. However, other shapes may be used, such as rectilinear footprints, or even a hemispherical nub wherein the contact surface with the front panel would be a point. The specific cross-sectional area ofnubs420 chosen would be determined by the level of visual inspection desired as well as by the manufacturing limitations of the process by which the secondary mirror is fabricated. Also to be taken into account is that the shape and size of the nubs should not be conducive to damaging the panel, which may be glass, against which they are being placed. Furthermore, the impact of the total surface area occupied by the nubs would need to be considered so as not to impact the bond strength of this joint.
FIG. 5A depicts an alternative embodiment of thesecondary mirror510. While previous embodiments have shownsecondary mirror510 to be a solid entity,FIG. 5 showssecondary mirror510 in the case where it is hollow. Moreover, an alternative nubs embodiment consisting of four nubs being present and equally distributed around the mountingsurface530 ofsecondary mirror510 is given. In this exemplary embodiment depicted in cross-section inFIG. 5B,nubs520 are integral tosecondary mirror510. That is,nubs520 are formed during the fabrication ofsecondary mirror510. Thenubs520 are shown to be cylindrical in nature, but as previously described, they may take the form of rectilinear or other shapes as desired to facilitate fabrication of the secondary mirror, or to aid in the process of assembling the solar power unit.Edges540 ofnubs520, in this embodiment as well as others described in this disclosure, are preferably filleted to prevent damage to the front panel when themirror510 is placed in contact with the front panel.
FIG. 6 illustrates a further embodiment ofprimary mirror610. In this embodiment,primary mirror610 is shaped such that there aretruncated sections620 of the curvedprimary mirror610. The truncated sections advantageously allow adjacent power units to fit tightly together in a solar array, thus maximizing the number of power units which can be packed into a solar energy system. For example, in the depicted configuration where there are four truncated sections, adjacent power units would fit together to form an orthogonal grid. The peaks of the truncated sections terminate in flat mountingtabs630, upon which nubs640 are placed or formed. In the truncated design, only the mountingtabs630 with thenubs640, rather than the entire perimeter ofprimary mirror610, are in contact with the front panel. The heights ofnubs640 are substantially equal, thus setting a substantially uniform gap for adhesive to be applied, and thus substantially aligning the primary mirror to the front panel.
Returning to the secondary mirror,FIG. 7 gives an exploded view of a template tool being used in the manufacturing process to securesecondary mirror710 tofront panel720.Template tool730 includes aprecision cutout740 for centeringsecondary mirror710 over the transparentfront panel720. It should be appreciated that for manufacturing an array of solar power units, thetemplate tool730 would incorporatemultiple cutouts740 for the multiple mirrors in the array.Template tool730 could also be a part of a larger tool which includes additional functionality. Whilecutout740 provides for proper planar positioning along the face offront panel720,nubs750 ensure that the mountingsurface760 ofsecondary mirror710 is aligned substantially parallel tofront panel720. That is, nubs provide alignment in the axis perpendicular to the front panel. Placement of themirror710 onto thefront panel720 could be achieved by automated machinery, in which case the fixed spacing provided by the nubs would have further importance in manufacturing reliability.
FIG. 8 is a simplified flowchart illustrating the basic steps in securing a mirror to the front panel. InFIG. 8,flowchart800 is entered atstep810. Step820 is first performed to position the template tool over the front panel. This can be accomplished by registering the template tool with the front panel using visual, mechanical, or other means well-known in the art (pin registration, magnetic or other sensing, etc.). Next, if the nubs are not integral to the mirror,step830 is performed to fix the nubs onto the mirror. Instep840, adhesive is dispensed onto either the front panel or mirror. Typically, the adhesive is dispensed in a discrete location or locations such as lines or dots. Instep850, the mirror is placed on the front panel through the aforementioned cutout on the template tool. Step860 is then performed to distribute the adhesive over the mounting surface of the secondary mirror. For example, in the case of a solid secondary mirror (FIG. 4), the adhesive could be first applied in two lines forming an “X” instep840. Then, rotating the mirror instep860 would distribute the adhesive across the circular mounting surface. In the case of a hollow secondary mirror (FIG. 5A), the adhesive could be dispensed in dots between the nubs. Rotation of the mirror instep860 would then distribute the adhesive around the perimeter of the mirror's mounting surface. In an alternative embodiment, after the adhesive is applied, compression may be used to distribute the adhesive between the mounting surface of the mirror and the front panel. This pressure could be applied through the mirror, through the front panel or from both sides.
Still referring toFIG. 8,step870 provides verification of proper adhesion. In the preferred embodiment, after the adhesive has been distributed the operator would verify instep870 whether the nubs are in full contact with the front panel. Verification methods could include a qualitative visual check, or quantitative means such as measurement of the mirror height before and after bonding. Failure for all nubs to be in contact would imply that a uniform adhesive gap has not been achieved, and that the mirror is misaligned. In this case, step880 calls for adjusting mirror placement. Adjustment could involve such measures as applying more pressure to the mirror or removing excess adhesive which may have seeped under the nubs. Once it is verified that nubs are properly in contact with the front panel, the subassembly is complete.
Although embodiments of the invention have been discussed primarily with respect to specific embodiments thereof, other variations are possible. Lenses or other optical devices might be used in place of, or in addition to, the primary and secondary mirrors or other components presented herein. For example, a Fresnel type of lens could be used to focus light on the primary optical element, or to focus light at an intermediary phase after processing by a primary optical element. Beyond solar energy systems, nubs may be used to align a lens in an optical assembly, or to provide spacing with respect to mating components.
It may be possible to use non-planar materials and surfaces with the techniques disclosed herein. Other embodiments can use optical or other components for focusing any type of electromagnetic energy such as infrared, ultraviolet, radio-frequency, etc. There may be other applications for the fabrication method and apparatus disclosed herein, such as in the fields of light emission or sourcing technology (e.g., fluorescent lighting using a trough design, incandescent, halogen, spotlight, etc.) where the light source is put in the position of the photovoltaic cell. In general, any type of suitable cell, such as a photovoltaic cell, concentrator cell or solar cell can be used. In other applications it may be possible to use other energy such as any source of photons, electrons or other dispersed energy that can be concentrated.
Steps may be performed by hardware or software, as desired. Note that steps can be added to, taken from or modified from the steps in this specification without deviating from the scope of the invention. In general, any flowcharts presented are only intended to indicate one possible sequence of basic operations to achieve a function, and many variations are possible.
While the specification has been described in detail with respect to specific embodiments of the invention, it will be appreciated that those skilled in the art, upon attaining an understanding of the foregoing, may readily conceive of alterations to, variations of, and equivalents to these embodiments. These and other modifications and variations to the present invention may be practiced by those of ordinary skill in the art, without departing from the spirit and scope of the present invention, which is more particularly set forth in the appended claims. Furthermore, those of ordinary skill in the art will appreciate that the foregoing description is by way of example only, and is not intended to limit the invention.