Tracking system for solar energy collection

A tracking system is provided for positioning solar energy collection units to face the sun during daylight hours. The collectors are mounted generally in north-south alignment with rotatable connections to a supporting base. The connections are laterally offset from the center of gravity of the collector. Thus, the weight of the collector ends to rotate the collector about the connection points to bring the center of gravity to the lowest possible point, thereby orienting the collector generally to face the western horizon. A rotation restraint mechanism is provided to prevent the uncontrolled rotation of the collector to a degree coordinated with rotation of the earth relative to the sun, thereby positioning the collector to directly face the sun during daylight hours. A rank of collectors in parallel alignment can be connected for tandem rotation under the control of a single rotation restraining mechanism. Rotation restraint can be effectuated by means of an electric brake or by a solenoid actuated pawl and ratchet gear.

FIELD OF THE INVENTION 
The present invention relates to solar energy collection devices in which a 
collector, sensitive to solar radiation, is oriented to face the sun and 
to change orientation to track the sun as the earth rotates in order to 
maximize the collection of solar energy. 
BACKGROUND OF THE PRIOR ART 
Various solar energy collection arrangements have been devised which employ 
collector panels or reflectors and which are directed at the sun in order 
to efficiently collect solar energy. Many of the applications of solar 
tracking systems have been implemented in connection with parabolic 
reflectors, since proper attitude of parabolic reflector troughs is more 
critical than is the orientation of flat solar collection panels. 
Parabolic reflector troughs are generally of uniform cross section and 
have a concave highly reflective parabolic surface which receives the rays 
of the sun and reflects this solar radiation into a longitudinally 
extending concentrator pipe conducting a heat transfer medium and located 
at the parabolic focus. The reflected solar energy is absorbed in the heat 
transfer medium, usually a liquid, which flows through the pipe to a heat 
exchanger. 
In prior art systems employing parabolic reflectors, the desirablity of 
maintaining the trough in proper orientation relative to the position of 
the sun overhead has been recognized and considerable effort has been 
directed to implementing workable tracking systems. All conventional 
systems heretofore employed, however, have been significantly deficient in 
one or more respects. In the simplest arrangement, where manual 
orientation is contemplated, the solar collection panels are seldom 
properly oriented, with the result that energy collection is only 
occassionally conducted at maximum efficiency. Electromechanical systems 
have been implemented to maintain proper orientation, but these systems 
have all involved an inordinate consumption of energy in the process. For 
example, one and three quarter horsepower motors have been employed to 
rotate reflector dishes or troughs of conventional solar collection 
systems. The amount of energy necessary to effectuate rotation detracts 
significantly from the net energy output achieved using conventional solar 
collection systems of this type. 
In all of the foregoing prior art systems, some positive drive system has 
been necessary to alter the orientation of the collector. That is, it has 
heretofore been necessary to drive some mass to effectuate rotation of the 
collector during the daylight hours in order to maintain proper collector 
orientation toward the sun. The energy expended in this manner has 
seriously detracted from the overall benefits to be gained by solar 
tracking. That is, such collector systems tend to utilize a significant 
portion of their increased energy output for their own operation, and 
hence do not significantly improve the net energy output as productive 
solar energy. The required energy consumption is aggravated with increased 
size of collector systems which are necessary in order to provide a 
sufficient energy output to justify the initial cost of maintenance of a 
solar energy collection system. 
In the aforesaid U.S. Pat. Application Ser. No. 744,290, a system of much 
greater simplicity was implemented. The embodiment depicted in that 
application involves the lateral movement of a counterweight relative to 
the rotational axis of a solar collection device to tilt the collector to 
a controlled degree. That is prior to solar noon, the counterweight is 
laterally offset from the axis of rotation to tilt the collector toward 
the east. At solar noon the counterweight is positioned in a vertical 
plane passing through the center of gravity and the rotational axis of the 
collector. After solar noon the counterweight is offset from the axis of 
rotation to tilt the solar collector toward the west. While this 
arrangement is quite advantageous in overcoming the defects of the prior 
art, the present invention represents an even greater improvement. 
It is an object of the present invention to provide a solar energy tracking 
arrangement which does not require the movement of a mass of a magnitude 
proportional to the mass of the solar collector. Rather, the present 
invention relies upon the force of gravity to effectuate rotation of the 
collector to maintain proper orientation toward the sun. Energy 
consumption during the daylight hours only occurs incident to the release 
of a locking system which opposes the force of gravity. The release 
mechanism, however, may be a very lightweight device and does not depend 
in any way upon the mass of the system to be controlled. Preferably, 
control of the tracking system is achieved by merely withdrawing a pawl 
from a ratchet gear for a short interval to allow the collector to rotate 
slightly. An alternative form of the invention involves momentarily 
disabling an electric brake which otherwise prevents rotation of the 
collector. In any form of the invention, rotation of the collector results 
the force of gravity acting upon it. After sunset when the collector no 
longer is able to receive solar energy, it may either be manually reset to 
an initial starting position from which it will begin progressing at 
sunrise, or it may be driven by a very low power motor through a high gear 
ration, since repositioning of the collector need not be completed before 
dawn. 
A particularly advantageous feature of the invention is its application to 
flat plate collectors. Previously, tracking systems had not generally been 
applied to flat plate collectors because any increase in efficiency 
resulting from a tracking system applied to flat plate collectors could 
not be justified by the expense of the tracking system. However, it has 
been found that an overall increase in efficiency of 30 percent is to be 
expected by applying the present invention to a flat plate solar energy 
collection panel system. That is, by employing the tracking system of the 
present invention the number of flat plate solar collection panels that 
are required to produce a given energy output is decreased by 30 percent. 
Furthermore, because of the simplicity of the tracking system of the 
present invention, tracking with flat plate collectors can be achieved 
without modification of the collector panels themselves and with a minimal 
investment for a tracking system. 
A further object of the invention, especially as applied to flat plate 
collectors, is to obtain an advantage in facilitating maintenance. In 
conventional systems, rectangular collectors are packed side by side in a 
fixed rectilinear array. Consequently, a defect in an interiorally located 
flat plate collector panel is extremely difficult to reach and service. 
Using the tracking and orientation system of the present invention, 
however, the panels need merely be tilted on edge to provide a passageway 
for access to service, repair and replace interiorally located panels. 
A further feature of the invention is the tandem interconnection of 
collectors in which the rotation of one collector can be transmitted to 
induce a uniform rotation in all of the collectors using a single rotation 
restraint applied to a single collector. 
A result of utilization of the invention is that the increase in efficiency 
in a flat plate solar energy collection system achieves a critical goal 
which is necessary for the application of solar energy to refrigeration. 
In order to be able to refrigerate to any commercially meaningful degree, 
temperatures of at least 212.degree. F. must be achieved for a significant 
refrigerating effect to occur. Conventional flat plate collector systems 
in stationary arrays are able to achieve consistent temperatures of only 
about 180.degree. F. However, by implementing the tracking system of the 
present invention, temperatures in excess of 212.degree. F. may be 
achieved using flat plate collector systems. This opens up the entire 
range of cooling applications to implementation by solar energy. This is 
especially significant since in those areas where the ground surface 
availability of solar energy is greatest, such as in desert areas, the 
requirement for air conditioning and other refrigeration is especially 
great. By increasing the energy collection of solar energy by thirty 
percent, as is possible using the present invention, the available output 
in refrigeration capacity of flat plate collector systems is increased by 
50 percent during the solar cycle. Thus, not only does the present 
invention achieve a raw increase in efficiency in solar energy collection, 
it also expands the efficiency of energy utilization in refrigeration by 
an even greater percentage. 
The effect of increased efficiency in solar energy collection achieved by 
the present invention utilizing flat plate collectors may be numerically 
determined by considering the amount of energy lost in flat plate solar 
panels that are oriented at other than perpendicular incidence to solar 
radiation. At an angle of 10.degree. relative to normal incidence, there 
is an energy collection loss of 1 1/2%. At 15.degree. this loss increases 
to 3 1/2% while at 20.degree. and 25.degree. the losses are 6% and 9 1/2% 
respectively. It can thus be seen that in conventional flat plate 
collector systems the efficiency of solar energy collection is less than 
90% throughout the greater portion of the solar day with the exception of 
that time period between 10 am and 4 pm. Since this maximum efficiency 
period encompasses only four hours out of a 10 hour solar day, and since 
the present invention increases collection efficiency to over 90% 
throughout the entire solar day, the magnitude of the advance achieved 
through the present invention may be appreciated.

DETAILED DESCRIPTION OF THE EMBODIMENT 
With reference to FIG. 1 an embodiment of the invention is depicted in 
which a rectangular flat plate solar energy collection panel 10 is mounted 
upon a support 11 which has longitudinal parallel rails 17 from which 
upright standards 18 and 19 extend and converge at opposed elevated 
sleeve-like mounting bearings 12, one of which is visible in FIG. 1. The 
bearings 12 are longitudinally aligned, generally in a north-south 
direction. The collector 10 has an expansive light receiving surface 9 and 
is journaled to the bearings 12 by means of pins 13 that extend axially 
through the bearings. The pins 13 form the connections between the 
collector 10 and the support 11 and are laterally offset from the center 
of gravity 14 of the collector 10. That is, the axis 15, which is a line 
passing through both of the connecting pins 13 at either end of the 
collector 10, is offset to the east of the center of gravity 14 when the 
flat light receiving surface 9 is in tangential alignment relative to the 
earth's surface and normal to the incidence of the sun's ray at solar 
noon. As a result of the lateral displacement of the axis of rotation 15 
from the center of gravity 14, the weight of the collector 10 acting at 
the center of gravity 14 tends to rotate the collector 10 to a position 
with the light receiving surface 9 facing the western horizon of the earth 
and with the center of gravity 14 and the connecting pins 13 lying in a 
plane passing through the gravitational center of the earth. That is, the 
weight of the collector 10 tends to cause it to rotate until the center of 
gravity 14 reaches its lowest possible location, which occurs when the 
collector 10 is approximately vertical with the light receiving 9 facing 
the western horizon. 
A rotation restraining lock 16 is mounted on the support 11 and is 
connected to the collector 10 for controlling the rotation of the flat 
plate collector 10 to prevent it from assuming the vertical position which 
it would otherwise seek. The rotation restraining lock 16 governs the 
rotation of the collector 10 to direct the light receiving surface 9 
toward the sun during daylight hours. 
The support 11 includes elongated longitudinal metal rails 17 formed of 
tubular steel which lie parallel to each other in contact with the earth's 
surface and extend generally in a north-south direction. At the 
extremities of the rails 17 upright metal support standards 18 and 19, 
also of tubular steel, are provided. The standards 18 rise from the rails 
17 and converge together at their upper extremities to meet at a vertical 
stub 22 which supports the southernmost mounting bearing 12. The standards 
18 are braced to the rails 17 by means of angle bars 20 welded both to the 
rails 17 and to the standards 18. 
The northernmost bearing 12 will typically be higher than the opposing 
bearing in the northern hemisphere, while the converse is true in the 
southern hemisphere. The differential elevation is governed by the 
geologic longitude of the location of the collector 10. That is, a greater 
height differential will exist between the bearings 12 for a collector 
located near the artic circle as contrasted with a collector located near 
the equator. The differential and mounting height also depends upon the 
date of the year, as the relative migration of the sun between the Tropics 
of Cancer and Capricorn also influences the proper elevational 
differential between the mountings 12. 
The upright standards 18 as well as the metal standards 19 converge 
together at their upper ends at their respective positions on the support 
11 in a universal joint which includes an upright stub 22 having a 
horizontal upper surface. The arrangement for the standards 19 is depicted 
in FIG. 8, although a similar arrangement for the other mounting 12 exists 
at the southernmost end of the support 11. To the flat upper surface of 
the stub 22 are welded two opposing angles 23 spaced apart from each other 
to define a gap therebetween extending in a north-south direction. A 
T-shaped member 24 has a lateral plate 25 from the center of which a leg 
26 extends perpendicularly downward parallel to and between the upward 
extending legs of the angles 23. A single cylindrical pivot pin 27 extends 
transversely through the upwardly extending legs of the angles 23 and 
through the downwardly extending leg 26 of the T-shaped member 24 to form 
an axis of rotation extending in an east-west direction. The pin 27 is 
equipped with an enlarged head at one extremity and with a transverse 
aperture carrying a knockout pin at the other extremity, to entrap the 
T-shaped member 24 between the angles 23 for rotation relative thereto. A 
bracket 28 extends in an arc and is bolted at its ends to the lateral 
plate 25 of the T-shaped member 24 to define an aperture therebetween to 
carry an annular bearing race 29 to complete the bearing 12. The bearing 
race 29 in turn receives a connecting pin 13 that extends longitudinally 
from the collector 10. A universal joint and bearing assembly similar to 
that of FIG. 8 is provided at the low or southernmost end of the support 
11 where the standards 18 converge. 
The arrangement of FIG. 8 is advantageous in that it accomodates 
adjustments in height of the standards 19, which may be formed of 
telescoping members. A thumbscrew 85 is provided and extends transversely 
through the wall of the outer tubular member of each of the standards 19 
to affectuate a secure engagement relative to the interior tube. Height 
adjustments can thereby be made in the standards 19 to alter the elevation 
of the northernmost end of the collector 10 to properly orient the 
collector to directly face the sun. The universal joint of the type 
depicted in FIG. 8 allow this to be done without disrupting the 
interconnection between the collector 10 and support 11, since the 
T-shaped member 24 will merely rotate to accomodate the changes in 
alignment. Thus, the connecting pins 13 are prevented from binding within 
the bearing races 29 since the pins 13 and bearing races 29 are varied 
together in their orientation. 
The flat plate collector 10 is of a conventional commercial variety in 
which a shallow hollow rectangular panel is formed with a heat transfer 
fluid flowing therethrough within a serpentine tube lying within the 
panel. A cover forming the light receiving surface 9 and transparent to 
solar radiation protects the tubing from the environment and causes the 
panel to act like a greenhouse, trapping the sun's rays to raise the 
temperature of the heat transfer fluid within the tubing. The tubing 
normally enters and exits the collector panel through a central aperture 
in one or both of the connection pins 13. If the inlet and outlet are 
combined at a single one of the connections pins 13, they may be formed in 
either a concentric arrangement or they may be separate and adjacent to 
each other. Heated fluid leaving the collector 10 is pumped through a heat 
exchanger where the heat energy extracted from the solar radiation is 
either stored or transformed to some other form of energy, such as 
electrical power. 
The connection pins 13 are normally linearly aligned along an axis 15 which 
passes to the right of the center of gravity of the collector 10 when 
viewed from the heat absorbing surface 9. The connection pins 13 at the 
two ends of the collector 10 can, however, be either horizontally or 
vertically offset from each other if desired. It is necessary only that 
the center of gravity 14 lie to the left of a line extending between the 
two connection pins 13, so that if unrestrained, the collector 10 will 
tilt so that the light collecting surface 9 faces generally toward the 
western horizon. 
A rotation restraining system may take one of several forms. For example, 
the electric brake 16 of FIGS. 1, 4 and 5 may be employed. In the electric 
brake system 16 an angle 30 may be bolted or welded to one of the 
standards 18 and gear reducing transmission 31 is mounted on the angle 30. 
A small electric drive motor 32 in turn is supported on the transmission 
31 and is used to reel in a cord 33 wound about a pulley 34 connected at 
the output of the transmission 31 to reposition the collector 10 at night. 
The electric brake 16 acts as a clutch and normally secures the pulley 34 
to the cylindrical output shaft 35 of the transmission 31 so that the 
pulley 34 normally moves with the shaft 35 and is prevented from rotating 
unless the shaft 35 is driven by the motor 32. The motor 32 is normally 
inactive, however, during daylight hours and is actuated only at night to 
reposition the collector 10. 
The electric brake 16 has a sleeve shaped cover 36 terminating at one end 
in an annular rim 37 which is rigidly secured to the pulley 34. Within the 
other end of cover 36 is a disk shaped end wall 38 with a central 
cylindrical aperture therethrough for receiving the output shaft 35 of the 
transmission 31. The disk shaped end wall 38 is keyed to the shaft 35 and 
is normally interconnected to the sleeve 36 by means of a brake shoe 
arrangement similar to that utilized in automotive vehicles. The brake 
shoes 39 are illustrated in FIG. 7 and are pivoted together about a pivot 
pin 40 extending from a reinforced mounting block 41 that is secured to 
the end wall 38. The brake shoes 39 are normally biased outward to engage 
the sleeve 36 by means of a compressed spring 42 which acts against 
pedestals 43 located on the interior surfaces of the brake shoes 39. The 
spring 42 rotates the brake shoes 39 outward away from each other about 
the pivot pin 40. Thus, the spring 42 is of sufficient strength to 
effectuate engagement between the annular sleeve 36 and the end wall 38, 
and hence the shaft 35. In its normal condition the brake 16 causes 
rotation of the shaft 35 to control rotation of the pulley 34. Rotation of 
the shaft 35, as previously noted, normally would occur only at night 
during repositioning of the collector panel 10 to face the eastern 
horizon. 
During the daylight hours, however, a timer mechanism periodically 
activates solenoid 44 which includes armatures connected by wires to the 
interior surfaces of the brake shoes 39. Upon actuation, the solenoid 44 
draws inward on the armatures which in turn pull the brake shoes 39 in 
rotation towards each other pivoting them in opposing directions of 
rotation about the pivot pin 40. When drawn inward in this manner, the 
brake shoes 39 release the sleeve 36 to a sufficient degree so that the 
weight of the collector 10, acting at the center of gravity 14, is able to 
rotate the collector to track the path of the sun across the sky. When the 
solenoid 44 is actuated, the sleeve 36, depicted in FIG. 5 is released 
from engagement with the end wall 38 and is turned to allow a portion of 
the cord 33 to be drawn upward as the cord connection pin 45 on the 
collector 10 rises. The weight at the center of gravity 14 of the 
collector 10 causes the collector to rotate, thereby raising the cord 
connection pin 45. Unless additional cord is released, however, the 
collector 10 is prevented from turning in response to the gravitational 
force of the weight of the collector panel, and hence rotation of the 
collector 10 is controlled. 
An alternative embodiment of a rotation restraining mechanism is depicted 
in FIG. 6. In this arrangement, a ratchet wheel 46 is journaled to the 
connection pin 13 at the southernmost end of the collector panel 10 and is 
rigidly connected thereto to rotate with the collector 10. Inclined braces 
47 extend downward at an angle from the underside of a flat support deck 
49 at the southernmost end of the collector 10 and secure the flat support 
deck 49 in a fixed disposition relative to the support 11 by welded 
attachment to the standard 18 at locations not depicted. The deck 49 is 
located outside of the universal connection joint joining the support 11 
and the collector 10. The ratchet wheel 46 is divided into two types of 
teeth, each encompassing about 180.degree. of the circumference of the 
ratchet wheel. The teeth 51 are formed at spaced intervals about a portion 
of the circumference of the ratchet wheel 46 as indicated and define 
semicircular grooves therebetween. The semicircular grooves are shaped to 
receive a latching bar 52 mounted on a pawl 53 which is hinged for 
rotation so that the latching bar 52 can be moved radially relative to the 
ratchet wheel 46. The opposing end of the pawl 53 is mounted at a 
rotatable connection 54 to a bracket 55 extending from the underside of 
the deck 49. 
The other portion of the circumference of the ratchet wheel 46 is equipped 
with teeth 56 which form a saw tooth configuration designed to receive 
another pawl 57 on the side of the ratchet wheel 46 opposite the pawl 53. 
The pawl 57 is under the influence of a counterclockwise bias by means of 
a coil spring 58 acting upon it and wrapped about the pivot connection pin 
59. In this way, the pawl 57 is biased into engagement with the ratchet 
teeth 56. Slightly above the rotation connection 59 is located a 
microswitch housing 60 having a microswitch lever 61 extending into the 
path in which the pawl 57 is moved by counterclockwise rotation of the 
ratchet wheel 46. Thus, such counterclockwise rotation of the ratchet 
wheel 46 causes the pawl 57 to actuate the microswitch 60 by tripping the 
switch lever 61 thereon. 
The microswitch 60 is mounted rigidly onto a support bar 62, which in turn 
is securely connected to the deck 49. Coil springs 63 and 64 are attached 
to the pawl 53 and extend in opposite directions to create opposing forces 
on the pawl 53. The coil spring 63 is attached to the mounting bar 62 and 
tends to rotate the pawl 53 clockwise to cause engagment of the latching 
bar 52 in the semicircular recesses between the teeth 51. The spring 64 is 
connected to a solenoid assembly 65 which may be actuated periodically to 
withdraw an armature 66, which acts through the spring 64 to overcome the 
force of the spring 63 and to rotate the pawl 53 counterclockwise and 
withdraw the latching bar 52 from the ratchet wheel 46. 
The electrical circuitry for the rotation restraining mechanism of FIG. 6 
is depicted in FIG. 7. The circuit includes a timer 65 which has contacts 
67' that are normally open. When the timer circuit is actuated, the 
contacts 67' close thereby providing power to the coil 68 of the solenoid 
assembly 65 through the normally closed contacts 69 to draw the solenoid 
armature 66 inward, thereby disengaging the latching bar 52 from the 
ratchet wheel 46. Once the latching bar 52 has been withdrawn from the 
ratchet wheel 46, the ratchet 46 will begin to rotate with the entrapped 
connection pin 13 and the collector panel 10 in a counterclockwise 
direction as viewed in FIG. 6. The pawl 57 then rides up the incline of a 
passing tooth 56 to trip the switch lever 61 of the microswitch 60. The 
normally open contacts of the microswitch 60 are depicted at 60' in FIG. 
7. When these contacts are closed by the action of the pawl 57, current 
flows through the power leads 70 to provide electrical power to a relay 71 
located within the solenoid assembly 65. The relay 71 opens the normally 
closed contact 69 of the solenoid assembly 65 and closes the normally open 
contacts 72 associated therewith in order to maintain the relay 71 in the 
circuit despite the reopening of the points 60' that will occur as soon as 
the ratchet tooth 56 has passed the pawl 57 so that the pawl 57 releases 
the microswitch lever 61. The relay 71 thereby disables the solenoid 
assembly 65 by opening the points 69, and the spring 63 acts upon the pawl 
53 to draw the latching bar 52 inward to engage the latching wheel 46 at 
the next sequential semicircular depression between teeth 51. The relay 71 
is deactivated to allow the contacts 72 to open and the contacts 69 to 
close when the timer circuit 67 opens the contacts 67'. The process is 
repeated periodically to allow the collector 10 to rotate with the ratchet 
wheel 46 in a counterclockwise direction as viewed in FIG. 6. 
Instead of a timer circuit for actuating the rotation restraining devices 
of the invention, a photodetection unit 73 may be employed to provide a 
power connection to the solenoid assembly 65 in FIG. 6 or the solenoid 44 
in FIG. 5. The photodetection unit 73 is depicted in FIG. 1 and is 
oriented on the ledge 48 and includes a pair of matched photosensors, one 
positioned in each of two adjacent compartments 74 and 75. The outputs of 
the photosensors in these two compartments are compared in conventional 
analog logic circuitry and the differential of the output is used to 
actuate a switch to provide power on the leads 70. 
Preferably, an entire rank of collectors 10 are mounted in parallel 
orientation and are arranged at spaced intervals in an east-west 
direction. A single rotation restraining mechanism, such as depicted in 
FIGS. 4 and 5, need be associated with but a single collector 10 in order 
to operate all of the collectors in the rank depicted in FIG. 2. In this 
arrangement, the collectors 10 are connected by a tandem linkage that 
includes a pulley 77 located at the end of each collector 10. A drive line 
78 is connected at one end to the pulley 77 of the first collector 10 by 
means of a set screw and clamp connection 79. The drive line 78 then 
extends to the next pulley 77, preferably through some form of elastic 
strain relief, such as a coil spring 80. A separate spring 80 is 
interposed in the drive line 78 between adjacent pulleys 77. The drive 
line 78 then looped over each of the interior pulleys 77 and is secured 
thereto by a set screw and clamp 79 so that one point on the drive line 78 
is rigidly attached to each pulley 77. The drive line 78 is then extended 
on to the next pulley through a strain relief coil spring 80 so that all 
of the collectors 10 may be operated in tandem, and controlled rotational 
movement of one collector is transmitted to all of the collectors. 
In the operation of the invention, the low power electric motor 32 is 
activated overnight to drive the shaft 35 through the transmission 31. 
This reels in the cord 33 and winds it about the pulley 34 in FIG. 4, thus 
drawing the cord connection pin 45 downward to rotate the collector 10 
clockwise in FIG. 1 until it is approximately vertical and facing the 
eastern horizon. This motion is transmitted through all of the collectors 
10 of FIG. 2 so that all are uniformly oriented to receive the sun's rays 
perpendicular to the light receiving surface 13 as the sun rises. As the 
sun progresses in its path of relative movement overhead, the timing 
mechanism 67 or photosensor 73 momentarily disables the rotation 
restraining mchanism, which may be either the electric brake of FIGS. 4 
and 5 or the ratchet restraining system of FIGS. 6 and 7. In either event, 
the collectors 10 undergo stepped tandem movement in counterclockwise 
rotation. This movement is caused by the weight of the collector panels 10 
which, acts at the centers of gravity 14. Since the collectors are each 
eccentrically mounted about the connection pins 13 they rotate from an 
east facing to a west facing orientation throughout the course of the day. 
As previously indicated, however, uncontrolled rotation is prevented by the 
rotation restraint system employed except during temporary periods of 
deactivation of the rotation restraining device. At these times the 
collector panels 10 are free to turn to maintain an orientation toward the 
sun. 
The springs 80 interconnecting the pulley 77 associated with the different 
collectors 10 accomodate uneven forces that may be applied to the 
different collectors 10, such as by gusts of wind that may momentarily 
disorient the collectors to a varying degree. 
It can be seen that very little energy is expended in controlling the 
rotation of the collectors panels 10 according to the invention. The force 
of gravity is the principal moving force, and need only be overcome in 
resetting the collectors 10 at night for use the following morning. 
Because of the long period throughout which the collectors 10 may be 
repositioned, a very low power motor 32 may be employed for this purpose. 
Also, because there is no power drain during the day, the usable power 
produced by the solar collectors is available for maximum utilization 
during the day time. This is particularly advantageous in refrigeration 
applications where an incremental increase in energy output at the maximum 
operating capability of the collectors produces exceptionally large 
benefits in refrigeration effects. Thus an increment in output in a sense 
achieves a bonus in results. 
It is to be understood that various alternative embodiments and 
modifications of the invention will become readily apparent to those 
familiar with the collection of solar energy. For example, while the 
invention has been illustrated in connection with flat plate collectors, 
it is equally applicable to collectors that employ parabolic reflector 
troughs. Also, the rotation restrain need not limit rotation to stepped 
advances, but can allow a slow, continuous rotation of the collector. 
Moreover, a wide variety of rotation controlling devices will undoubtedly 
become readily apparent. The invention, therefore, should not be limited 
by the specific embodiments disclosed herein, but rather is defined in the 
claims appended hereto.