Abstract:
An apparatus for collecting solar energy wherein a heat exchange array of plastic or the like is protected against damage by excessive heat buildup. The array is housed in a normally closed chamber having a portion transparent to solar rays and the chamber is periodically vented by means responsive to heat expansion of the enclosed array. The invention permits substantial cost reductions in solar heat exchanges; particularly of the type adapted to heat buildings, swimming pools and domestic water systems.

Description:
SUMMARY OF THE INVENTION 
     The invention is directed to an improved heat collector for solar systems. Specifically, it solves a problem associated with the so-called &#34;greenhouse&#34; type of collector wherein a solar absorber-heat exchanger is enclosed in a housing having a glazed surface for exposure of the absorber to solar rays. The invention permits the safe substitution of plastic absorber-exchangers for ones of copper or other metals currently costing many times that of the plastics employed herein. Use of plastic in greenhouse collectors has heretofore involved the danger of severe damage to the plastic by heat buildup within the closed structure housing the absorber-exchanger unless some means of removing excess heat resulting from a failure of the fluid circulation system is provided. The invention utilizes thermal expansion of the plastic absorber-exchanger to vent the collector interior to ambient air if a preselected temperature is exceeded, thus permitting the safe use of plastic arrays. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a plan view of a greenhouse type collector incorporating the invention; 
     Fig. 2 is a partial vertical section taken along line 2--2 of FIG. 1; 
     FIG. 3 is a view of that portion of the device shown in FIG. 2 with the uppermost glazed cover element raised by expansion of a housed array by the suns rays; and 
     FIG. 4 shows an alternate embodiment of the device shown in FIGS. 1, 2 and 3. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     FIG. 1 shows a &#34;greenhouse&#34; type solar heat collector generically designated by reference numeral 10 and incorporating the invention. A housing 12, which may be of a suitable metal or plastic encloses an elongate solar abosorber-heat exchanger generically designated 14 and including a manifold 16 for fluid inlet from conduit 18 through flexible connector 20 to a plurality of tubular elements 22 connected in fluid flow relation thereto. A second manifold 24 is fixed to the opposite ends of elements 22, also in fluid flow relation thereto and leads through a rigid connector 26 to an outlet conduit 28. The opposite end of manifold 24, not shown, is suitably fixed to housing 12 to prevent movement of that end of the exchanger in respect to housing 12 in response to expansion or contraction of the entire assembly as the internal temperature of the collector varies as described below. 
     As shown in FIGS. 1 and 2, housing 12 may be of the configuration of a generally rectangular pan-line container with side walls 27, end walls 29 and bottom wall 30 as best shown in FIGS. 2 through 4. Housing 12 may be a stamping if of metal or molded or extruded if of a plastic of a type later described. The open face of housing 12 is positioned in use toward the sun and is normally closed by a planiform light transparent element or cover 33, glazed either with a suitable transparent plastic film or with glass. Exchanger 14 is supported within housing 12 on a plurality of bar-like elements 32 disposed in parallel spaced relation longitudinally of the exchanger. Elements 32 find their support on bottom wall 30 of housing 12 to extend transversely thereof as shown in FIG. 2, with tubular elements 22 resting upon but not attached to bar elements 32. Since the left hand end of the absorber-exchanger 14 (as shown in FIG. 1) is fixed to housing 12 and the right hand end is connected to housing 12 through flexible connector 20, the tubular array, slidably supported on bars 32 is free to expand or contract with heat changes within housing 12. As the temperature therein approaches a level which might cause damage to array 14, the non-fixed right hand end of the array has expanded slightly in the direction of the longitudinal arrow, FIG. 3. 
     The exchanger, particularly the tubular elements 22, may be of plastic such as acrylonitrile/butadiene/styrene (ABS) or polyvinyl chloride (PVC) and preferably loaded with carbon black or the like for optimum heat absorption. Such materials have a coefficient of expansion of from 6 to 13 × 10 -5  /° F. Housing 12 as above mentioned, may be fabricated of a glass filled plastic (fiberglass) or of steel or aluminum (thermal expansivity of from 0.4 to 1.3 × 10 -5  /° F.). A thermal insulation layer may be provided on the inner surfaces of the housing to reduce the passage of solar heat to the exterior. A temperature differential of 100° F. will cause array 14 (if fabricated 10 feet long) to expand approximately one inch relative to housing 12. Such differential motion is employed as below described to open and close cover 33 as shown in FIGS. 2, 3 and 4. As best shown in FIGS. 2 and 3 when the temperature within housing 12 is below a preselected critical level, housing cover 33 is drawn into snug marginal engagement with the open end housing by the combined weight of cover 33 and a pair of springs 36. Springs 36 are maintained in tension by the lever arms 38 of a pair of bellcranks generically designated 40. A shaft 42 fixed to and extending transversely of housing sidewalls 27 provides pivotal mounting for bellcranks 40. The vertical bellcrank arms 44 are pivotally attached to the outermost elements 22 of array 14 by pintle bolts 46. A pair of springs 48 are mounted in fixtures 50 on opposite side walls of housing 12 and are normally maintained under compression by the weight of cover 33 and the tension of springs 36 when bellcranks 40 are in their normal position as shown in FIG. 2. 
     As above mentioned, array 14 (of an assumed length of ten feet) will expand longitudinally some 1 inch in response to a temperature differential of 100° F. relative to the housing 12 when fabricated of certain materials above described. The device is designed normally to assume the FIG. 2 position until the internal housing temperature approaches a level considered likely to damage plastic exchanger 14. Such expansion moves the free end of the exchanger 14 in the horizontal arrow direction of FIG. 3 position. Arms 38 then rotate clockwise to relieve the tension on springs 36 sufficiently to allow compression springs 48 to raise cover 33 sufficiently to vent the interior of housing 12 with ambient air. As the internal temperature gradually drops with resultant contraction of the exchanger 14, bellcranks 40 are rotated counter-clockwise, increasing the tension of springs 36 sufficiently to compress springs 48 to the FIG. 2 position with resultant closure of cover 33. 
     An alternative embodiment of the device is shown in FIG. 4, wherein bellcranks 40 have their vertical lever arms mounted to lugs 52 to project outwardly of manifold 16 in the plane of exchanger 14. Bellcranks 40 are pivoted to housing 12 at 54, with arms 38 extending outwardly from the exchanger 14 and biased counter-clockwise by tension springs 56. As the exchanger 14 expands, the lever arms 38 are pivoted counter-clockwise to relieve the tension of springs 56 and cover 33 is raised by springs 48 in the manner above described.