SYSTEMS FOR DAMPING A SOLAR PHOTOVOLTAIC ARRAY TRACKER
Solar tracker systems include a torque tube, a column supporting the torque tube, a solar panel attached to the torque tube, and a damper assembly. The damper assembly includes an outer shell surrounding an inner shell. A piston is at least partially positioned within the inner shell and moveable relative thereto. An active lock of the damper assembly includes a housing positioned within the outer shell. The housing defines a cavity and a housing channel extending from the cavity to an outer fluid channel. A shaft extends into the cavity and a valve assembly is attached to the shaft. The shaft is rotatable within the cavity between an unsealed position in which the housing channel is in fluid communication with the cavity, and a sealed position in which the valve assembly is rotationally aligned with the housing channel and obstructs fluid communication between the cavity and the housing channel.
This application claims the benefit of U.S. Provisional Patent Application No. 63/199,643, filed Jan. 14, 2021, which is incorporated herein by reference in its entirety.
FIELD OF THE DISCLOSUREThe field relates generally to systems for solar tracking and damping a photovoltaic (PV) array. In some embodiments, the system includes a damper assembly that absorbs external loads, such as wind, on the photovoltaic array, and may be actively locked to prevent damage.
BACKGROUNDSolar arrays are devices that convert light energy into other forms of useful energy (e.g., electricity or thermal energy). One example of a solar array is a photovoltaic (PV) array that converts sunlight into electricity. Some photovoltaic arrays are configured to follow or track the path of the sun to minimize the angle of incidence between incoming sunlight and the photovoltaic array.
Photovoltaic array assemblies include a movable mounting system that supports and tilts the photovoltaic array and connects it to an anchoring structure. During use, the photovoltaic array may be exposed to environmental loads such as wind load, which can wear and cause damage to various components of the array. Such array assemblies typically include some type of damper system to absorb external forces acting on the array and prevent damage. Known damper systems provide a resistance force in response to external forces acting on the panel during normal operation. However, some such damper systems allow for flexing rotational movement of the panels and may therefore not be well suited to manage high intermittent loads acting on the panels. For example, during extreme weather events, such as a high wind event, it may be desirable to lock the panels in a flat orientation to reduce drag on the panels and prevent wear in the tracker system. Accordingly, a need exists for systems for damping photovoltaic arrays that provide traditional damping during normal operation yet also serve as a torsional locking mechanism during high load events.
This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the disclosure, which are described and/or claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
SUMMARYIn one aspect, a solar tracker system includes a torque tube, a column supporting the torque tube, a solar panel attached to the torque tube, and a damper assembly having a first end pivotably connected to the torque tube and a second end pivotably attached to the column. The damper assembly includes an inner shell and an outer shell surrounding the inner shell. An outer fluid channel is defined radially between the inner shell and the outer shell. The damper assembly also includes a piston at least partially positioned within the inner shell and moveable relative thereto and an active lock. The active lock includes a housing positioned within the outer shell and defining a cavity and a housing channel extending from the cavity to the outer fluid channel. The active lock further includes a shaft extending into the cavity and a valve assembly attached to the shaft. The shaft is rotatable within the cavity between an unsealed position in which the housing channel is in fluid communication with the cavity, and a sealed position in which the valve assembly is rotationally aligned with the housing channel and obstructs fluid communication between the cavity and the housing channel.
In another aspect, a damper assembly for use in a solar tracker system includes an inner shell and an outer shell surrounding the inner shell. An outer fluid channel is defined radially between the inner shell and the outer shell. The damper assembly also includes a piston at least partially positioned within the inner shell and moveable relative thereto and an active lock positioned within the outer shell. The active lock includes a housing defining a cavity and a housing channel extending from the cavity to the outer fluid channel. The active lock further includes a shaft extending into the cavity and a valve assembly attached to the shaft. The shaft is rotatable within the cavity between an unsealed position in which the housing channel is in fluid communication with the cavity, and a sealed position in which the valve assembly is rotationally aligned with the housing channel and obstructs fluid communication between the cavity and the housing channel.
In yet another aspect, a solar tracker system includes a column, a solar panel pivotably connected to the column, and a damper assembly configured for absorbing external loads on the solar panel. The damper assembly includes an inner shell and an outer shell surrounding the inner shell. The outer shell and the inner shell cooperatively define a fluid circuit of the damper assembly. The fluid circuit includes a radial channel extending between the inner shell and the outer shell. The damper assembly further includes a piston at least partially positioned within the inner shell for moving fluid within the fluid circuit and an active lock positioned within the outer shell. The active lock includes a housing defining the radial channel, a shaft extending into the housing, and a valve assembly attached to the shaft. The shaft is configured to rotate within the housing to move the valve assembly into alignment with the radial channel and obstruct a flow of fluid within the fluid circuit.
Various refinements exist of the features noted in relation to the above-mentioned aspects of the present disclosure. Further features may also be incorporated in the above-mentioned aspects of the present disclosure as well. These refinements and additional features may exist individually or in any combination. For instance, various features discussed below in relation to any of the illustrated embodiments of the present disclosure may be incorporated into any of the above-described aspects of the present disclosure, alone or in any combination.
36672-237
Corresponding reference characters indicate corresponding parts throughout the drawings.
An example embodiment of a solar tracker system 100 including a PV solar array row 102 is shown in
The solar array row 102 includes a mounting assembly 110 that supports the plurality of solar panel assemblies 104. The mounting assembly 110 includes a torque tube 112 to which the solar panel assemblies 104 are connected. The solar panel assemblies 104 may be connected to the torque tube 112 by any suitable method including, for example, fasteners such as bolts and clips or by a clamping device. The solar panel assemblies 104 pivot about a rotational axis that extends through the torque tube 112 (i.e., extending into the page in
The torque tube 112 of this embodiment is pivotably connected to a plurality of support columns 116. In the illustrated embodiment, the support columns 116 are I-beam posts. Other support columns 116 may be used in other embodiments (e.g., a tubular support column 116). The support columns 116 may be connected to a base 118, shown as a foundation in the ground-mounted embodiment of
The mounting assembly 110 also includes a drive 120 that adjusts the position of the solar panel assemblies 104. The drive 120 causes the torque tube 112 to pivot relative to the support columns 116. The drive 120 is disposed between the torque tube 112 and a base 118 (
Referring to
Referring to
The torque tube 112 of
The mounting assembly 110 of
The damper assembly 126 of
The solar panel assembly 104 in the first orientation is oriented at a first oblique angle el relative to the longitudinal axis Li. In the second orientation, the solar panel assembly 104 is oriented at a second angle 02 relative to the longitudinal axis Li. In p the third orientation, the solar panel assembly 104 is oriented at a third oblique angle θ3 relative to the longitudinal axis L1, and in an opposite direction from the first orientation. In the illustrated embodiment, the first angle and third angle are approximately the same. More specifically, the first angle and the third angle are approximately 80 degrees and the second angle θ2 is approximately 90 degrees. The solar array row 102 is operable to orient the panel assembly about the rotational axis, by rotating the torque tube 112 relative to the support columns 116, such that the panel assembly is substantially vertical and faces a first direction and such that the panel assembly is substantially vertical and faces a second opposite direction. In other words, the panel assembly may be rotated such that the panel assembly is substantially parallel with the longitudinal axis L1 and faces to the right of the page in
The solar panel assembly 104 in the second orientation of
As the panel assembly is moved between the first orientation and the third orientation, the piston 136 is retracted into the outer tube 134 of the damper assembly 126. In particular, when the panel assembly is in the first orientation of
Referring to
The piston 136 is received within the inner tube 144 and includes a piston seal 154 that seals against an interior wall of the inner tube 144 to inhibit fluid flow therethrough. As the piston 136 is moved within the inner tube 144 the piston seal 154 causes fluid to be displaced within the primary fluid circuit 152. For example, as the piston 136 is extended out of the inner tube 144, fluid on a first side 158 of the piston seal 154 is directed out of the inner tube 144 and into the return path 150, thereby pushing fluid through the active damper lock 148, the binary damper valve assembly 146, and into the inner tube 144 on a second side 160 of the piston seal 154. Likewise, as the piston 136 is retracted into the inner tube 144, the piston 136 pushes fluid in the inner tube 144 on the second side 160 of the piston seal 154 through the binary damper valve assembly 146, the active damper lock 148, and the return path 150 into the inner tube 144.
The binary damper valve assembly 146 of this embodiment passively changes flow resistance of the primary fluid circuit 152 by transitioning between a high resistance state and a low resistance state based on the velocity of the piston 136. In particular, during operation, as movement of the piston 136 within the inner tube 144 is increased, a velocity of fluid flow through binary damper valve assembly 146 is also increased. As described in greater detail with respect to
Accordingly, the binary damper valve assembly 146 of the
The threshold piston 136 speed is suitably set or controlled between approximately 0.01 cm/s and 100 cm/s, or approximately 0.1 cm/s and 10 cm/s, or approximately 0.5 cm/s and 5 cm/s. In the embodiment of
When the binary damper valve assembly 146 is in the low resistance state, the damper assembly 126 may provide a resistance force of between approximately 0 and 5 kilonewtons. More specifically, in the embodiment of
The active damper lock 148 of
When the active damper lock 148 is in the sealed state, the damper assembly 126 may provide a resistance force of between approximately 5 and 100 kilonewtons, between approximately 25 and 75 kilonewtons, and/or between approximately 35 and 65 kilonewtons. More specifically, in the embodiment of
The accumulator 140 is coupled in flow communication with the primary fluid circuit 152 by an accumulator flow path 153 to receive and contain excess fluid from the primary fluid circuit 152. For example, as described above, during operation, the damper assembly 126 provides resistance to movement of the piston 136 within the inner tube 144 by restricting fluid flow from the first side 158 of piston 136 to the second side 160. When the piston 136 is fully extended from the tube, the primary fluid circuit 152 contains a first volume of fluid. However, as the piston 136 is retracted into the inner tube 144 (e.g., as a result of pivoting the solar panel assemblies 104 on the torque tube 112), at least a portion of the first volume of fluid is displaced from the primary fluid circuit 152 to receive the added volume of the retracted piston 136. The accumulator 140 provides a reservoir for excess fluid that is displaced from the primary fluid circuit 152 by the added volume of the piston 136 in the inner tube 144. In other embodiments, the damper assembly 126 does not include the accumulator 140 or the accumulator flow path 153.
The outer tube 134 circumscribes the inner tube 144 and defines an outer fluid channel 170 extending radially between the outer tube 134 and the inner tube 144. An inner fluid channel 172 is defined radially between the piston 136 and the inner tube 144.
The inner fluid channel 172 and the outer fluid channel 170 are in fluid communication via at least one aperture 174 defined in the inner tube 144. In particular, in the embodiment of
The piston 136 of
The damper assembly 126 further includes the binary damper valve assembly 146, the piston seal 154, the piston 136, the inner tube 144, an inner tube retainer 186, the outer tube 134, a lock shaft 190, a lock shaft retainer 192, a controller assembly 194, and the accumulator 140. The outer tube 134 includes an active lock plate 196 which defines an aperture 198 sized to receive the lock shaft 190 therein. The controller assembly 194 removably attaches to the active lock plate 196 and is sized to house electronics and the drive 168 (
The controller assembly 194 is removably attachable to the outer tube 134 (e.g., via fasteners) and extends outward therefrom, as shown in
The binary damper valve chamber 204 is sized to threadably receive the binary damper valve assembly 146 (
The active lock chamber 206 extends from an opening 216 in an outer circumferential surface 218 of the lock housing 182 to a distal end 220. A second passageway 222 provides fluid communication between the active lock chamber 206 and the outer fluid channel 170 (shown in
The binary damper valve assembly 146 includes the binary valve 162, a biasing assembly 164 that includes a first biasing element 165 and a second biasing element 167, the valve body 226, and a seal 228. The biasing elements 165, 167 of this embodiment are compression springs and the seal 228 is an O-ring. In other embodiments, the binary damper valve assembly 146 includes any suitable biasing elements 165, 167 and seal 228 that enables the binary damper valve assembly 146 to function as described.
The valve body 226 defines a tunnel 230 sized to receive the binary valve 162 therein. Referring to
Referring to
The binary valve 162 includes a suitable material such as a polymer material. For example, the binary valve 162 is made or formed of Delrin plastic. (Delrin is a registered trademark of E.I. Du Pont De Nemours and Company corporation). In other embodiments, the binary valve 162 is made of any material that enables the binary damper valve assembly 146 to function as described herein.
The biasing assembly 164 biases the binary valve 162 within the valve body 226 to the low resistance state. In particular, the biasing elements 165, 167 are each positioned within the binary valve 162 to engage the intermediate sidewalls. More specifically, the first biasing element 165 engages a tunnel face 258 of the valve body 226 and a first intermediate sidewall 254 of the binary valve 162. The second biasing element 167 engages the rear face 212 of the binary damper valve chamber 204 and the first intermediate sidewall 254 of the binary valve 162. Collectively, the biasing elements 165, 167 bias the binary valve 162 within the valve body 226 such that the first axial end 248 of the binary valve 162 is spaced from the tunnel face 258 and the second axial end 250 is spaced from the rear face 212. In other embodiments, the binary valve 162 includes a plurality of intermediate sidewalls and the biasing elements 165, 167 each engage and contact a different sidewall.
During operation, with the binary damper valve assembly 146 in the low resistance state, as the piston 136 retracts into the inner tube 144, fluid between the piston seal 154 and the lock housing 182 is directed from the inner tube 144 through the channel in the threaded channel member 236 and into the tunnel 230. The fluid flow entering the tunnel 230 applies pressure on the intermediate sidewall 254 of the binary valve 162. The fluid flow within the binary valve 162 is directed radially outward between the first axial end 248 of the binary valve 162 and the tunnel face 258 and axially along the outer surface 242 of the binary valve 162 within the channels (
The active damper lock 148 is suitably a spool valve that includes the lock shaft 190 received within the active lock chamber 206 to define the longitudinal lock axis L3. The lock shaft 190 defines a recessed region 270 that is aligned with the second fluid passageway when the active damper lock 148 is in the unsealed state. The lock shaft 190 further defines an abutment 272, also referred to herein as a “radial projection”, having a circumference that is greater than the circumference of the lock shaft 190 at the recessed region 270. In particular, the abutment 272 is sized to contact the active lock chamber 206 and inhibit fluid flow longitudinally therethrough. The active lock further includes seals 271, 273, 274 attached to the lock shaft 190. The seals include a first seal 271 that is generally aligned with the first passageway 214 and spaced from the chamber wall 217 when the active damper lock 148 is in the unsealed state. A second seal 273 is included adjacent a distal end 276 of the lock shaft 190. A third seal 274 is included longitudinally above the first seal 271 and the abutment 272 to further prevent fluid from flowing longitudinally above the third seal. In other embodiments, the active damper lock 148 may include any valve that enables the active damper lock 148 to function as described herein.
During operation, when the active damper lock 148 is in the unsealed state and the piston 136 is caused to retract into the inner tube 144, fluid flow from the first passageway 214 is directed into the recessed region 270 between the lock shaft 190 and the active lock chamber 206. The fluid is further directed longitudinally toward the distal end 276 of the lock shaft 190 and into the second passageway 222. At least some of the fluid may further be directed into the third passageway 224 (
Referring to
Similarly, referring to
In one alternative embodiment, the inner surface 240 of the binary valve 162 may include one or more flow features (not shown) for reducing turbulent fluid flow and eddy currents within the binary valve 162. For example, in one alternative embodiment, the binary valve 162 includes inner ridges 244 (not shown) protruding radially inward from the inner surface 240 and extending axially of the binary valve 162. In the alternative embodiment, the inner ridges 244 define inner channels therebetween for directing fluid flow from the intermediate sidewalls 254 to the corresponding axial ends and along the outer surface 242 (
In the sealed state, the lock shaft 190 is positioned such that the abutment 272 is longitudinally aligned with and covers the first passageway 214. Moreover, each of the first seal 271, the second seal 273, and the third seal 274 contact and seal against the chamber wall 217 when the active damper lock 148 is in the sealed state. In the embodiment of
As described above with respect to
As shown in
The accumulator 140 also includes an additional fluid (not shown) on the first side 308 of the piston assembly 298 that moves the piston assembly 298 within the accumulator tube 278 in response to fluid leaving the accumulator tube 278. In particular, in the example embodiment, a gas is included within the accumulator tube 278 on the first side 308 of the accumulator piston assembly 298 to prevent loose movement of the piston assembly 298 within the accumulator tube 278. In the example embodiment, the gas is an inert gas, specifically nitrogen, though any suitable gas may be used in other embodiments.
During assembly, the piston 136 of the damper assembly 126 is first extended to approximately a midway extension position and the accumulator piston assembly 298 is positioned approximately midway between the connecting port 280 and the end cap 290. The end cap 290 is removed and the nitrogen is introduced into the first portion of the accumulator tube 278 on the first side of the piston 136. The end cap 290 is then closed, sealing the nitrogen within the accumulator tube 278. As the piston 136 of the damper assembly 126 is retracted into the inner tube 144, the piston assembly 298 of the accumulator 140 is moved toward the end cap 290 by the added fluid from the primary fluid circuit 152 entering the accumulator 140 and the nitrogen is pressurized in the first portion of the accumulator tube 278. As the piston 136 of the damper assembly 126 is extended from the inner tube 144 and fluid is drawn back from the accumulator tube 278 and into the primary fluid circuit 152, the pressurized nitrogen on the first side of the accumulator piston assembly 298 moves the accumulator piston assembly 298 within the accumulator tube 278 to fill the space resulting from the reduced fluid volume. In other embodiments, the nitrogen gas may be added to the accumulator tube 278 with the piston 136 of the damper assembly 126 in any position. For example, in one embodiment the nitrogen gas is provided in the accumulator tube 278 with the piston 136 of the damper assembly 126 extended to a distance that it would be in with the panels in the stow position. In another embodiment, the nitrogen gas is provided in the tube with the piston 136 of the damper assembly 126 fully extended. In further embodiments, a biasing element (e.g., a compression spring as shown in the embodiment of
The binary valve 562 of
As shown in
When the binary damper valve assembly 546 is in the high resistance state, the damper assembly 126 may provide a resistance force of between approximately 5 and 35 kilonewtons, between 10 and 30 kilonewtons, or between 15 and 25 kilonewtons. More specifically, in the embodiment of
As the piston 136 velocity decreases, the biasing elements 165, 167 transition the binary valve 562 to the low resistance state in a similar manner as the binary damper valve assembly 146 of
The damper assembly 626 extends between a first end 628 that is pivotably attachable to the linkage member 130 (
The accumulator 640 is coupled in flow communication with the fluid in the outer tube 634 and configured to function in substantially the same manner as described above with respect to the embodiment shown in
As shown in
In the unsealed state, fluid is permitted to flow from the inner tube 644 into the axial channel 607 of the lock housing 682 and into one of the radial channels 611. The lock housing 682 is received within the outer tube 634 such that the radial channels 611 extend to the outer fluid channel 670 of the damper assembly 626. Fluid within the active lock chamber 606 may also flow around the shaft 690 to the accumulator channel 613.
Referring to
Referring to
The shaft 790 defines a central bore 723 that contains a valve assembly 725 (
Referring to
The sleeve 727 includes a biasing element 731 received therein that engages a ball 733, also referred to herein as a “valve,” and biases the ball 733 radially outward of the shaft 790. As the shaft 790 is rotated to the sealed state, the ball 733 is positioned in alignment with the radial channel 711 and the biasing element 731 biases the ball 733 radially outward to block and/or obstruct the radial channel 711 from fluid communication with the cavity 721. The biasing element 731 provides a sufficient biasing force on the ball 733 such that the ball 733 is not displaced by heavy tension loads on the damper assembly. In other embodiments, a different biasing element may be used such that a desired tension load on the damper assembly causes fluid pressure on the ball 733 to overcome the biasing force of the biasing element 731 and permit at least some fluid flow between the ball 733 and the radial channel 711. To transition the active damper lock 748 to the unsealed state, the shaft 790 is rotated 90 degrees in the opposite direction to move the ball 733 out of alignment with the radial channel 711 and permit fluid communication between the radial channel 711 and the cavity 721. In the illustrated embodiment, the valve assembly 725 is a ball check valve. In other embodiments the valve assembly 725 may include any valve assembly 725 that enables the active damper lock 748 to function as described herein.
The first zone 802 includes a first zone controller 808 communicatively coupled to a wind sensor 810. The wind sensor 810 may be coupled in either wireless or wired communication with the first zone controller 808. The wind sensor 810 is operable to detect a wind speed within the first zone 802 and transmit the wind speed to the first zone controller 808. The first zone controller 808 is coupled in communication with each solar array row 804 in the first zone 802 and is operable to control each solar array row 804 based on the wind speed detected by the wind sensor 810. In other embodiments, the first zone 802 includes a plurality of wind sensors 810 (not shown) positioned within the first zone 802. In some such embodiments, the first zone controller 808 approximates an average wind speed over the first zone 802 based on the separate measurements received from the plurality of wind sensors 810. In yet further embodiments, a plurality of the solar array rows 804 or each solar array row 804 may include a wind sensor 810 coupled in communication with the row controller 812. In some such embodiments, the row controllers 812 control row operations (e.g., tracking and adjustment of active damper locks) based on the measurements received from the wind sensor 810 associated with the row 804.
Each solar array row 804 includes a row controller 812 coupled in communication with the first zone controller 808. In the embodiment of
The row controllers 812 are also communicatively coupled to a plurality of active lock device (ALD) drives 814 and a torque tube drive 816 associated with the row. In particular, the torque tube drive 816 is a slew drive substantially similar to the drive 120 shown in
As described in greater detail below, the row controllers 812 may be coupled in either wired or wireless communication with each of the ALD drives 814. Each row includes four ALD drives 814, each corresponding to a damper assembly on the row. In particular, in the embodiment of
Referring back to
The row controllers 812 are further communicatively coupled to an inclinometer 818. The inclinometer 818 is operable to detect an orientation of the panels and/or torque tube of the solar array row 804. The inclinometer 818 may include a gyroscope and/or accelerometer included within the row controller 812 assembly shown in
During operation, the wind sensor 810 detects and transmits a detected wind speed to the first zone controller 808. During normal operation, the row controllers 812 may perform a tracking operation, wherein the active damper locks are unsealed and each of the row controllers 812 controls the orientation of the rows 804 panel assemblies and torque tube based on a position of the sun in the sky.
When the first zone controller 808 determines that a wind event is occurring, based on the detected wind speed exceeding a predetermined threshold, the first zone controller 808 transmits a signal to each row controller 812 instructing the row controllers 812 to perform a stow operation in which each of the rows 804 are moved to the stowed position (e.g., by controlling the drives shown in
With the active locks sealed, once the wind sensor 810 detects that the wind speed has fallen below a predetermined threshold, the first zone controller 808 may transmit a signal to each of the row controllers 812 instructing the row controller 812 to resume the tracking operation. In response, the row controllers 812 control the ALD drives 814 to unseal each of the active damper locks and each of the rows 804 are moved back into a tracking orientation that is based on a position of the sun. The row controllers 812 may also be locally controlled (e.g., via an operator at the row controller 812 assembly) to perform the stow operation or the tracking operation.
The solar tracker system 800 is further operable to control the row controllers 812 to perform additional stow operations, in which the panel assemblies may be moved into different orientations, based on factors in addition to or other than wind speed. For example, as described above, the solar tracker system 800 in a wind-stow operation moves the panel rows 804 the into a wind stow position, in which the panel assemblies are oriented parallel to the base surface 118 (shown in
In the snow-stow and hail-stow operations, the panel assemblies are moved to and locked in a relatively steep orientation. In particular, in one embodiment, the panels are oriented such that the angle el (shown in
The row controller 812 includes a primary control unit 820 and a master unit 822. The primary control unit 820 controls row orientation operations (e.g., controlling the torque tube drive 816) while the master unit 822 communicates with and controls the ALD drives 814. In other embodiments, the master unit 822 controls the drive and row orientation operations. The master unit 822 is connected to the primary control unit 820 via a USB connection (e.g., via a USB port coupled to the primary control unit 820). The master unit 822 includes a transceiver (e.g., an antenna 828 as shown in
The power source 836 of the ALD drive unit 814 is a non-rechargeable battery, though the battery may be rechargeable in other embodiments. In particular, the power source 836 includes a lithium-ion cell stack having a 5-ampere hour capacity. The boost converter 838 is electrically coupled to the power source 836 and operable to convert the battery output voltage to 6 volts DC.
The locking system motor 842 is operable to drive the lock shaft 190 (
The SoC 846 is electrically coupled to the boost converter 838, the encoder 844, the H-bridge 840, the on-board antenna 848, the push buttons 850, and the LEDs 852. The SoC 846 may draw power from the boost converter 838 and selectively control the boost converter 838. The SoC 846 transmits a pulse width modification (PWM) signal to the H-bridge 840 to selectively control the H-bridge 840, and thereby selectively control operation and rotational direction of the locking system motor 842. The SoC 846 is configured to selectively adjust the speed of the locking system motor 842 (e.g., to change the speed of locking/unlocking the active damper lock) by adjusting the PWM signal to the H-bridge 840.
The encoder 844 and the on-board antenna 848 are also electrically coupled to the SoC 846. The onboard antenna 848 is a transceiver configured for two-way wireless communication with the row controller 812. In particular, the onboard antenna 848 is a Bluetooth low energy antenna. The encoder 844 tracks a state of the locking motor 842 (e.g., whether the active damper lock is in the sealed or unsealed state). In particular, the encoder 844 is a rotary encoder that senses an angular position of the shaft of the locking system motor 842 and transmits the detected position in the form of an electrical signal to the SoC 846. After a message from the row controller 812 to lock the active damper lock is received, the SoC 846 controls the locking system motor 842 to lock the active damper lock and the encoder 844 detects the changed position of the shaft. The SoC may also transmit a signal to the row controller 812 indicating a state of the locking system motor 842 based on the signal from the encoder 844.
The SoC 846 and the locking system motor 842 generally only draw power from the power source 836 either when a command has been provided from the row controller 812 (e.g., to lock or unlock the active damper lock) or to check whether a message has been received. As a result, the five-ampere hour capacity of the power source 836 has an expected life span of approximately 10 years with regular use.
The master unit 922 is connected to a motor port of the primary control unit 920 and to a USB port of the primary control unit 920. The motor port of the primary control unit provides electrical power from a power source (e.g., generated from the controller power panels shown in
Each ALD drive unit 914 is coupled to the row controller 912 via two power transmitting wires and two data transmitting wires. The power transmitting wires provide electrical power from the master unit (and received from the primary control unit via the motor port) to each of the ALD drive units 914. The received electrical power may be used by the ALD drive units 914 to power the unit's corresponding motors and sensors. The data transmitting wires are configured for two-way electrical communication between the row controller and the ALD drive units 914. The data transmitting wires are RS-485 standard wires. In other embodiments, the ALD drive units 914 may be coupled to the row controller 912 by any number and/or type of wires that enable the first solar array row 804 to function as described herein.
In some embodiments, the above-described systems and methods are electronically or computer controlled. The embodiments described herein are not limited to any particular system controller or processor for performing the processing tasks described herein. The term “controller” or “processor”, as used herein, is intended to denote any machine capable of performing the calculations, or computations, necessary to perform the tasks described herein. The terms “controller” and “processor” also are intended to denote any machine capable of accepting a structured input and of processing the input in accordance with prescribed rules to produce an output. It should also be noted that the phrase “configured to” as used herein means that the controller/processor is equipped with a combination of hardware and software for performing the tasks of embodiments of the disclosure, as will be understood by those skilled in the art. The terms “controller” and “processor”, as used herein, refers to central processing units, microprocessors, microcontrollers, reduced instruction set circuits (RISC), application specific integrated circuits (ASIC), logic circuits, and any other circuit or processor capable of executing the functions described herein.
The computer implemented embodiments described herein embrace one or more computer readable media, including non-transitory computer readable storage media, wherein each medium may be configured to include or includes thereon data or computer executable instructions for manipulating data. The computer executable instructions include data structures, objects, programs, routines, or other program modules that may be accessed by a processing system, such as one associated with a general-purpose computer capable of performing various different functions or one associated with a special-purpose computer capable of performing a limited number of functions. Aspects of the disclosure transform a general-purpose computer into a special-purpose computing device when configured to execute the instructions described herein. Computer executable instructions cause the processing system to perform a particular function or group of functions and are examples of program code means for implementing steps for methods disclosed herein. Furthermore, a particular sequence of the executable instructions provides an example of corresponding acts that may be used to implement such steps. Examples of computer readable media include random-access memory (“RAM”), read-only memory (“ROM”), programmable read-only memory (“PROM”), erasable programmable read-only memory (“EPROM”), electrically erasable programmable read-only memory (“EEPROM”), compact disk read-only memory (“CD-ROM”), or any other device or component that is capable of providing data or executable instructions that may be accessed by a processing system.
A computer or computing device such as described herein has one or more processors or processing units, system memory, and some form of computer readable media. By way of example and not limitation, computer readable media comprise computer storage media and communication media. Computer storage media include volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules or other data. Communication media typically embody computer readable instructions, data structures, program modules, or other data in a modulated data signal such as a carrier wave or other transport mechanism and include any information delivery media. Combinations of any of the above are also included within the scope of computer readable media.
As used herein, the terms “about,” “substantially,” “essentially” and “approximately” when used in conjunction with ranges of dimensions, concentrations, temperatures or other physical or chemical properties or characteristics is meant to cover variations that may exist in the upper and/or lower limits of the ranges of the properties or characteristics, including, for example, variations resulting from rounding, measurement methodology or other statistical variation.
When introducing elements of the present disclosure or the embodiment(s) thereof, the articles “a”, “an”, “the” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” “containing” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. The use of terms indicating a particular orientation (e.g., “top”, “bottom”, “side”, etc.) is for convenience of description and does not require any particular orientation of the item described.
As various changes could be made in the above constructions and methods without departing from the scope of the disclosure, it is intended that all matter contained in the above description and shown in the accompanying drawing[s] shall be interpreted as illustrative and not in a limiting sense.
Claims
1. A solar tracker system comprising:
- a torque tube;
- a column supporting the torque tube;
- a solar panel attached to the torque tube; and
- a damper assembly having a first end pivotably connected to the torque tube and a second end pivotably attached to the column, the damper assembly comprising: an inner shell; an outer shell surrounding the inner shell, wherein an outer fluid channel is defined radially between the inner shell and the outer shell; a piston at least partially positioned within the inner shell and moveable relative thereto; and an active lock comprising a housing positioned within the outer shell, the housing defining a cavity and a housing channel extending from the cavity to the outer fluid channel, the active lock further comprising a shaft extending into the cavity and a valve assembly attached to the shaft, the shaft being rotatable within the cavity between an unsealed position in which the housing channel is in fluid communication with the cavity, and a sealed position in which the valve assembly is rotationally aligned with the housing channel and obstructs fluid communication between the cavity and the housing channel, wherein the valve assembly further comprises a sleeve extending radially outward from the shaft towards the housing, a valve, and a biasing element positioned at least partially within the sleeve, the biasing element biasing the valve radially outward from the shaft.
2. The solar tracker system of claim 1, wherein the damper assembly defines a longitudinal axis extending through the first end and the second end, and wherein the shaft defines a longitudinal axis that is parallel to the longitudinal axis of the damper assembly.
3. The solar tracker system of claim 2, wherein the shaft is rotatable about the longitudinal axis of the shaft between the sealed position and the unsealed position.
4. The solar tracker system of claim 1 further comprising a drive operably engaged with the shaft to rotate the shaft between the sealed position and the unsealed position.
5. The solar tracker system of claim 1, wherein the shaft defines a threaded bore and the sleeve is threadably received within the bore of the shaft.
6. (canceled)
7. The solar tracker system of claim 1, wherein the valve covers the housing channel when the shaft is in the sealed position.
8. The solar tracker system of claim 1, wherein the valve assembly is a ball check valve.
9. The solar tracker system of claim 1, wherein the inner shell contacts the housing and at a least a portion of the housing is received within the inner shell.
10. The solar tracker system of claim 1, wherein the damper assembly defines a longitudinal axis extending through the first end and the second end, and wherein the housing channel extends perpendicular to the longitudinal axis from the cavity to the outer fluid channel.
11. A damper assembly for use in a solar tracker system, the damper assembly comprising:
- an inner shell;
- an outer shell surrounding the inner shell, wherein an outer fluid channel is defined radially between the inner shell and the outer shell;
- a piston at least partially positioned within the inner shell and moveable relative thereto; and
- an active lock positioned within the outer shell, the active lock comprising: a housing defining a cavity and a housing channel extending from the cavity to the outer fluid channel; a shaft extending into the cavity; and a valve assembly attached to the shaft, the shaft being rotatable within the cavity between an unsealed position in which the housing channel is in fluid communication with the cavity, and a sealed position in which the valve assembly is rotationally aligned with the housing channel and obstructs fluid communication between the cavity and the housing channel, wherein the valve assembly further comprises a sleeve extending radially outward from the shaft towards the housing, a valve, and a biasing element positioned at least partially within the sleeve, the biasing element biasing the valve radially outward from the shaft.
12. The damper assembly of claim 11, wherein the piston is moveable along a longitudinal axis of the damper assembly, and wherein the shaft defines a longitudinal axis that is parallel to the longitudinal axis of the damper assembly.
13. The damper assembly of claim 12, wherein the shaft is rotatable about the longitudinal axis of the shaft between the sealed position and the unsealed position.
14. The damper assembly of claim 11 further comprising a drive operably engaged with the shaft to rotate the shaft between the sealed position and the unsealed position.
15. (canceled)
16. (canceled)
17. The damper assembly of claim 11, wherein the valve covers the housing channel when the shaft is in the sealed position, and wherein the valve assembly includes a ball check valve.
18. The damper assembly of claim 11, wherein the piston is moveable along a longitudinal axis of the damper assembly, and wherein the housing channel extends perpendicular to the longitudinal axis from the cavity to the outer fluid channel.
19. (canceled)
20. (canceled)
21. A damper assembly for use in a solar tracker system, the damper assembly comprising:
- an inner shell;
- an outer shell surrounding the inner shell, wherein an outer fluid channel is defined radially between the inner shell and the outer shell;
- a piston at least partially positioned within the inner shell and moveable relative thereto; and
- an active lock positioned within the outer shell, the active lock comprising: a housing defining a cavity and a housing channel extending from the cavity to the outer fluid channel; a shaft extending into the cavity; and a valve assembly attached to the shaft, the shaft being rotatable within the cavity between an unsealed position in which the housing channel is in fluid communication with the cavity, and a sealed position in which the valve assembly is rotationally aligned with the housing channel and obstructs fluid communication between the cavity and the housing channel, wherein the shaft defines a threaded bore, the valve assembly comprising a sleeve that is threadably received within the bore of the shaft.
22. The damper assembly of claim 21, wherein the piston is moveable along a longitudinal axis of the damper assembly, and wherein the shaft defines a longitudinal axis that is parallel to the longitudinal axis of the damper assembly.
23. The damper assembly of claim 22, wherein the shaft is rotatable about the longitudinal axis of the shaft between the sealed position and the unsealed position.
24. The damper assembly of claim 21, wherein the valve assembly covers the housing channel when the shaft is in the sealed position, and wherein the valve assembly includes a ball check valve.
Type: Application
Filed: May 13, 2021
Publication Date: Jul 14, 2022
Inventors: Joseph D. LoBue (Dale, TX), Nagendra Srinivas Cherukupalli (Cupertino, CA), Tamilarasan Mouniandy (Chennai), Milo Zabala (Concord, CA)
Application Number: 17/302,826