This disclosure relates generally to architectural opening covering assemblies and, more particularly, to methods and apparatus to control an architectural opening covering assembly.
Architectural opening covering assemblies such as roller blinds provide shading and privacy. Such assemblies generally include a motorized roller tube connected to covering fabric or other shading material. As the roller tube rotates, the fabric winds or unwinds around the tube to uncover or cover an architectural opening.
Wherever possible, the same reference numbers will be used throughout the drawing(s) and accompanying written description to refer to the same or like parts. As used in this patent, stating that any part (e.g., an object, a layer, structure, area, plate, etc.) is in any way positioned on (e.g., positioned on, located on, disposed on, or formed on, etc.) another part, means that the referenced part is either in contact with the other part, or that the referenced part is above the other part relative to Earth with one or more intermediate part(s) located therebetween. Stating that any part is in contact with another part means that there is no intermediate part between the two parts.
An example architectural opening covering assembly disclosed herein includes a tube and a covering coupled to the tube such that rotation of the tube winds or unwinds the covering around the tube. The example architectural opening covering assembly also includes a motor operatively coupled to the tube to rotate the tube and a gravitational sensor to generate tube position information based on a gravity reference. The example architectural opening covering assembly further includes a controller communicatively coupled to the motor to control the motor. The example controller is to determine a position of the covering based on the tube position information.
An example tangible computer readable storage medium disclosed herein includes instructions that, when executed, cause a machine to at least determine an angular position of a tube of an architectural opening covering assembly via a gravitational sensor. Rotation of the example tube is to lower or raise an architectural opening covering. The example tangible computer readable storage medium further includes instructions that, when executed, cause the machine to determine a position of the architectural opening covering based on the angular position of the tube.
Another example tangible computer readable storage medium disclosed herein includes instructions that, when executed, cause a machine to at least operate a motor to rotate a tube of an architectural opening covering assembly including an architectural opening covering coupled to the tube such that rotation of the tube winds or unwinds the architectural opening covering around the tube. The example tangible computer readable storage medium further includes instructions that, when executed, cause the machine determine angular positions of the tube via a gravitational sensor while the motor is being operated and determine an angular position of the tube at which the architectural opening covering is substantially fully unwound.
An example architectural opening covering assembly disclosed herein may be controlled by a controller. In some examples, the example architectural opening covering assembly includes a motor and gravitational sensor communicatively coupled to the controller. The motor rotates a tube about which a covering is at least partially wound. Thus, if the motor rotates the tube, the covering is raised or lowered.
In some examples, the gravitational sensor generates tube position information and/or determines an angular position of the tube based on gravity (e.g., determining an angular position relative to a gravitational field vector of Earth). In some examples, by determining a number of rotations of the tube from a predetermined position (e.g., a fully unwound position, a fully wound position, etc.), the position of the covering is determined.
In some examples, the gravitational sensor is an accelerometer (e.g., a capacitive accelerometer, a piezoelectric accelerometer, a piezoresistive accelerometer, a Hall Effect accelerometer, a magnetoresistive accelerometer, a heat transfer accelerometer and/or any other suitable type of accelerometer). Other examples employ other types of gravitational sensors such as, for example, a tilt sensor, a level sensor, a gyroscope, an eccentric weight (e.g., a pendulum) movably coupled to a rotary encoder, an inclinometer, and/or any other suitable gravitational sensor.
In some examples, the gravitational sensor is used to determine if a manual input (e.g., a force such as a pull applied to the covering or any other part of the assembly) is provided. In some instances, in response to the manual input, the example controller controls the motor to move the covering, stop movement of the covering, and/or counter the manual input to prevent lowering or raising the covering past a threshold position such as, for example, a lower limit position or an upper limit position.
In the example illustrated in
The example architectural opening covering assembly 100 is provided with a motor 120 to move the covering 106 between the raised and lowered positions. The example motor 120 is controlled by a controller 122. In the illustrated example, the controller 122 and the motor 120 are disposed inside the tube 104 and communicatively coupled via a wire 124. Alternatively, the controller 122 and/or the motor 120 may be disposed outside of the tube 104 (e.g., mounted to the headrail 108, mounted to the mounts 115, located in a central facility location, etc.) and/or communicatively coupled via a wireless communication channel.
The example architectural opening covering assembly 100 of
In some examples, the architectural opening covering assembly 100 is operatively coupled to an input device 138, which may be used to selectively move the covering 106 between the raised and lowered positions. In some examples, the input device 138 sends a signal to the controller 122 to enter a programming mode in which one or more positions (e.g., a lower limit position, an upper limit position, a position between the lower limit position and the upper limit position, etc.) are determined and/or recorded. In the case of an electronic signal, the signal may be sent via a wired or wireless connection.
In some examples, the input device 138 is a mechanical input device such as, for example, a cord, a lever, a crank, and/or an actuator coupled to the motor 120 and/or the tube 104 to apply a force to the tube 104 to rotate the tube 104. In some examples, the input device 128 is implemented by the covering 106 and, thus, the input device 138 is eliminated. In some examples, the input device 138 is an electronic input device such as, for example, a switch, a light sensor, a computer, a central controller, a smartphone, and/or any other device capable of providing instructions to the motor 120 and/or the controller 122 to raise or lower the covering 106. In some examples, the input device 138 is a remote control, a smart phone, a laptop, and/or any other portable communication device, and the controller 122 includes a receiver to receive signals from the input device 138. Some example architectural opening covering assemblies include other numbers of input devices (e.g., 0, 2, etc.). The example architectural opening covering assembly 100 may include any number and combination of input devices. Example architectural opening covering assemblies that can be used to implement the example architectural opening covering assembly 100 of
As mentioned above, the example gravitational sensor 126 is coupled to the mount 128 such that an axis of rotation of the gravitational sensor 126 is substantially coaxial to the axis of rotation 130 of the tube 104, which is substantially coaxial to a central axis of the tube. In the illustrated example, the center of the gravitational sensor 126 is disposed on (e.g., substantially coincident with) the axis of rotation 130 of the tube 104. As a result, when the tube 104 rotates about the axis of rotation 130, the gravitational sensor 126 is subjected to a substantially constant gravitational force (g-force) of about 1 g (i.e., the gravitational sensor 126 does not substantially move up and down relative to Earth). In other examples, the gravitational sensor 126 is disposed in other positions and experiences variable g-forces as the tube 104 rotates. As described below, the g-force provides a frame of reference independent of the angular position of the tube 104 from which the rotation and, thereby, an angular position of the tube 104 can be determined.
In the illustrated example, the gravitational sensor 126 is an accelerometer (e.g., a capacitive accelerometer, a piezoelectric accelerometer, a piezoresistive accelerometer, a Hall Effect accelerometer, a magnetoresistive accelerometer, a heat transfer accelerometer and/or any other suitable type of accelerometer). Alternatively, the gravitational sensor 126 may be any other type of gravitational sensor such as, for example, a tilt sensor, a level sensor, a gyroscope, an eccentric weight (e.g., a pendulum) movably coupled to a rotary encoder, an inclinometer, and/or any other suitable gravitational sensor.
Alternatively, any other sensor that determines the angular position of the tube 104 relative to one or more frame(s) of references that are independent of (e.g., substantially fixed or constant relative to) the angular position of the tube 104 may be utilized. For example, a sensor that generates tube position information based a magnetic field imparted by one or more magnets disposed outside of the tube 104 (e.g., on a wall, bracket, etc. adjacent the tube 104) may be employed by the example architectural opening covering assembly 100. Similarly, a sensor may generate tube position information based on a radio frequency (RF) signal transmitted from outside of the tube 104 (e.g., by detecting a strength of the RF signal, which may vary depending on the angular position of the sensor in and/or on the tube 104 relative to a RF signal transmitter, and so forth.
The gravitational sensor 126 of the illustrated example generates tube position information and transmits the tube position information to the controller 122. The example gravitational sensor 126 outputs a first signal associated with the first axis 1500 and a second signal associated with the second axis 1502. The first signal includes a first value (e.g., a voltage) corresponding to a g-force experienced by the gravitational sensor 126 along the first axis 1500. The second signal includes a second value (e.g., a voltage) corresponding to a g-force experienced by the gravitational sensor 126 along the second axis 1502. Thus, the tube position information generated by the example gravitational sensor 126 includes the first value and the second value, which are based on the orientation of the gravitational sensor 126. In the illustrated example, the gravitational sensor 126 substantially constantly outputs the first signal and/or the second signal. In some examples, the gravitational sensor 126 outputs the first signal and the second signal according to a schedule (e.g., the gravitational sensor 126 outputs the first signal and/or the second signal every one one-hundredth of a second irrespective of the detection of movement, etc.).
Each angular position of the gravitational sensor 126 and, thus, the tube 104 corresponds to a different first value and/or second value. Thus, the first value and/or the second value are indicative of an angular displacement of the gravitational sensor 126 relative to the gravitational field vector of Earth 1504. A combination of the first value and the second value is indicative of a direction of the angular displacement (e.g., clockwise or counterclockwise) of the example gravitational sensor 126 relative to the gravitational vector of Earth 1504. As a result, based on the first value and the second value, an angular position (i.e., the amount of angular displacement in a given direction relative to the gravitational vector of Earth 1504) of the tube 104 may be determined. A change in the first value and/or the second value is indicative of motion (i.e., rotation) of the tube 104. Thus, a rate of change of the first value and/or the second value is indicative of a speed of rotation of the tube 104, and a rate of change of the speed of rotation of the tube 104 indicates an angular acceleration of the tube 104.
In the illustrated example of
In the illustrated example of
In
As the tube 104 and, thus, the gravitational sensor 126 rotate about the axis of rotation 130, the first value and the second value of the first signal and the second signal, respectively, change according to the orientation (e.g., angular position) of the gravitational sensor 126. Thus, rotation of the tube 104 may be determined by detecting a change in the first value and/or the second value. Further, the angular displacement (i.e., amount of rotation) of the tube 104 may be determined based on the amount of change of the first value and/or the second value.
The direction of the angular displacement may be determined based on how the first value and/or the second value change (e.g., increase and/or decrease). For example, if the g-force experienced along the first axis decrease and the g-force experienced along the second axis decrease, the tube 104 is rotating counterclockwise in the orientation of
A revolution of the tube 104 may be determined and/or incremented by detecting a repetition of a combination of the first value and the second value during rotation of the tube 104. For example, if the tube 104 is rotating in one direction and a given combination of the first value and the second value repeat (e.g., a combination indicative of 1 g and 0 g for the first value and the second value, respectively), the tube 104 rotated one revolution from the angular position at which the combination of the first and second value corresponds (e.g., the first angular position).
In some examples, a rotational speed of the tube 104 is determined based on a rate of change of the angular position of the gravitational sensor 126. In some examples, the controller 122 determines the angular position of the tube 104, the rotational speed of the tube 104, the direction of rotation of the tube 104 and/or other information based on the tube position information generated by the gravitational sensor 126. In other examples, the tube position information includes the angular position of the tube 104, the rotational speed of the tube 104, and/or other information.
Based on the angular displacement (e.g., a number of revolutions) of the tube 104 from a reference position of the covering 106 (e.g., a previously stored position, a fully unwound position, a lower limit position, an upper limit position, etc.), a position of the covering 106 may be determined, monitored and/or recorded.
During operation of the example architectural opening covering assembly 100, the example gravitational sensor 126 transmits tube position information to the controller 122. In some examples, the controller 122 receives a command from the input device 138 to move the covering 106 in a commanded direction (e.g., to raise the covering 106, to lower the covering 106, etc.) and/or move the covering 106 to a commanded position (e.g., a lower limit position, an upper limit position, etc.). In some examples, based on the tube position information, the controller 122 determines a direction in which the tube 104 is to be rotated to move the covering 106 in the commanded direction, a number of (and/or a fraction of) revolutions of the tube 106 to move the covering 106 from its current position to the commanded position, and/or other information. The example controller 122 then transmits a signal to the motor 120 to rotate the tube 104 in accordance with the command. As the motor 120 rotates the tube 104 and winds or unwinds the covering 106, the gravitational sensor 126 transmits tube position information to the controller 122, and the controller 122 determines, monitors and/or stores the position of the covering 106, the number of revolutions of the tube 104 (which may be whole numbers and/or fractions) away from the commanded position and/or a reference position, and/or other information. Thus, the controller 122 controls the position of the covering 106 based on the tube position information generated by the example gravitational sensor 126.
In some examples, the user provides a user input that causes the tube 104 to rotate or rotate at a speed greater than or less than one or more thresholds of rotational speed of the tube 104 expected via operation of the motor 120 (e.g., by pulling on the covering 106, twisting the tube 104, etc.). In some examples, based on the tube position information generated by the example gravitational sensor 126, the controller 122 monitors movement of the tube 104 and detects the user input (e.g., based on detecting movement of the tube 104 (e.g., a rock and/or rotation, an angular acceleration, a deceleration, etc.) when the motor 120 is not being operated to move the tube 104). When the user input is detected, the controller 122 may operate the motor 120 (e.g., to counter or assist rotation of the tube 104).
In the illustrated example, the controller 400 includes an angular position determiner 402, a rotational direction determiner 404, a covering position determiner 406, an instruction processor 408, a memory 410 and a motor controller 412. During operation of the controller 400, the gravitational sensor 126 generates tube position information (e.g., voltages corresponding to g-forces experienced along dual axes of the gravitational sensor 126). The tube position information is transmitted to the angular position determiner 402 and/or the rotational direction determiner 404 (e.g., via a wire). In the illustrated example, the angular position determiner 402 processes the tube position information and/or determines an angular position of the tube 104 (e.g., relative to a gravitational field vector of Earth) based on the tube position information.
The example rotational direction determiner 404 of
In some examples, the example instruction processor 408 may receive instructions via the input device 138 to raise or lower the covering 106. In some examples, in response to receiving the instructions, the instruction processor 408 determines a direction of rotation of the tube 104 to move the covering 106 to a commanded position and/or an amount of rotation of the tube 104 to move the covering 106 to the commanded position. In the illustrated example, the instruction processor 408 sends instructions to the motor controller 412 to operate the motor 120.
The example memory 410 of
The example motor controller 412 sends signals to the motor 120 to cause the motor 120 to operate the covering 106 (e.g., lower the covering 106, raise the covering 106, and/or prevent (e.g., brake, stop, etc.) movement of the covering 106, etc.). The example motor controller 412 of
The example covering position determiner 406 of
While an example manner of implementing the controller 400 has been illustrated in
In the illustrated example, the controller 500 includes a voltage rectifier 501, a polarity sensor 502, a clock or timer 504, a signal instruction processor 506, the gravitational sensor 126, a tube rotational speed determiner 508, a rotational direction determiner 510, a fully unwound position determiner 512, a covering position monitor 514, a programming processor 516, a manual instruction processor 518, a local instruction receiver 520, a current sensor 522, a motor controller 524, and an information storage device or memory 526.
During operation, the example polarity sensor 502 determines a polarity (e.g., positive or negative) of a voltage source (e.g., a power supply) supplied to the controller 500. As described in further detail herein, the voltage source may be the input device 138 and/or may be provided via the input device 138. In some examples, the voltage source is conventional power supplied via a house wall and/or a building. In other examples, the voltage source is a battery. In the illustrated example, the input device 138 modulates (e.g., alternates) the polarity of the power supplied to the controller 500 to signal commands or instructions (e.g., lower the covering 106, raise the covering 106, move the covering 106 to position X, etc.) to the controller 500. The example polarity sensor 502 receives timing information from the clock 504 to determine the duration of modulations of the polarity of the voltage (e.g., to determine that the polarity was switched from negative to positive, and held positive for 0.75 seconds indicating that the covering 106 should be moved to 75% lowered). Thus, the illustrated example employs pulse width modulation to convey commands. The example polarity sensor 502 of the illustrated example provides polarity information to the rotational direction determiner 510, the memory 526, and the motor controller 524.
The voltage rectifier 501 of the illustrated example converts the signal transmitted by the input device 138 to a direct current signal of a predetermined polarity. This direct current signal is provided to any of the components of the controller 500 that are powered (e.g., the programming instruction processor 516, the memory 526, the motor controller 524, etc.). Accordingly, modulating the polarity of the power signal to provide instructions to the controller 500 will not interfere with the operation of components that utilize a direct current signal for operation. Although the illustrated example modulates the polarity of the power signal, some examples modulate the amplitude of the signal.
The example clock or timer 504 provides timing information using, for example, a real-time clock. The clock 504 may provide information based on the time of day and/or may provide a running timer not based on the time of day (e.g., for determining an amount of time that has elapsed in a given period). In some examples, the clock 504 is used to determine a time of day at which a manual input occurred. In other examples, the clock 504 is used to determine an amount of time elapsed without a manual input. In other examples, the clock 504 is used by the polarity sensor 502 to determine a duration of a modulation (e.g., polarity change).
The example signal instruction processor 506 determines which of a plurality of actions are instructed by the signal transmitted from the input device 138 to the example controller 500. For example, the signal instruction processor 506 may determine, via the polarity sensor 502, that a modulation of the input power (e.g., a signal having two polarity changes (e.g., positive to negative and back to positive) within one second) corresponds to a command to raise the example covering 106.
The example tube rotational speed determiner 508 determines a speed of rotation of the tube 104 using tube position information from the gravitational sensor 126. Information from the tube rotational speed determiner 508 facilitates a determination that a manual input is provided to the example architectural opening covering assembly 100. For example, when the motor 120 is operating and the tube 104 is moving faster or slower than the speed at which the motor 120 is driving the tube 104, the speed difference is assumed to be caused by a manual input (e.g., a user pulling on the covering 106).
The fully unwound position determiner 512 determines a position of the covering 106 where the covering 106 is fully unwound from the tube 104. In some examples, the fully unwound position determiner 512 determines the fully unwound position based on movement of the tube 104 as described in further detail below. Because the fully unwound position will not change for the covering 106 (e.g., unless the covering 106 is physically modified or an obstruction is present) the fully unwound position is a reference that can be used by the controller 500. In other words, once the fully unwound position is known, other positions of the covering 106 can be referenced to that fully unwound position (e.g., the number of rotations of the tube 104 from the fully unwound position to a desired position). If the current position of the covering 106 is later unavailable (e.g., after a power loss, after the architectural opening covering assembly 100 is removed and reinstalled, etc.), the controller 500 can move the covering 106 to a desired position by moving the covering 106 to the fully unwound position as determined by the fully unwound position determiner 512 and then rotating the tube 104 the known number of rotations to reach the desired position of the covering 106.
The example covering position monitor 514 of
The example rotational direction determiner 510 of
The example current sensor 522 of
The example manual instruction processor 518 of
In some examples, the example local instruction receiver 520 receives signals (e.g., a RF signal) from the input device 138. In some examples, the signals correspond to an action such as, for example, raising or lowering the covering 106. After receiving the signals from the input device 138, the example local instruction receiver 520 instructs the motor controller 524 to move the covering 106 based on the action corresponding to the signals.
The example programming processor 516 of
The example information storage device or memory 526 stores (a) rotational direction associations with polarity and operation of the motor 120, (b) commands or instructions and their associated signal patterns (e.g., polarity switches), (c) covering positions (e.g., current positions, preset positions, etc.), (d) amperages associated with operation of the motor 120, and/or (e) any other information.
The example motor controller 524 of
While an example manner of implementing the controller 500 has been illustrated in
Flowcharts representative of example machine readable instructions that may be executed to implement the example controller 122 of
As mentioned above, the example processes of
The example instructions 600 of
The motor controller 412 sends a signal to the motor 120 to rotate the tube 104 to move the covering 106 (block 606). While the tube 104 is rotating, the covering position determiner 406 determines an amount of angular displacement of the tube 104 relative to a previous angular position (block 608). For example, the covering position determiner 406 may increment an amount of rotation of the tube 104 relative to the previous angular position and/or subtract the previous angular position from an angular position determined based on tube position information generated by the gravitational sensor 126. The covering position determiner 406 may also increment a number of revolutions rotated by the tube 104.
The covering position determiner 406 adjusts a stored position of the covering 106 based on the amount of angular displacement of the tube 104 (block 610). The example covering position determiner 406 determines the position of the covering 106 relative to a reference position such as, for example, the lower limit position, the fully unwound position, etc. The position of the covering 106 may be determined in units of degrees, revolutions, and/or any other unit of measurement relative to the reference position. In some examples, the covering position determiner 406 determines the position of the covering 106 based on tube position information generated by the gravitational sensor 126, the angular position information determined by the angular position determiner 402, the angular displacement of the tube 104, and/or previously stored position information.
The covering position determiner 406 determines if rotation of the tube 104 is complete. For example, the covering position determiner 406 may determine if the covering 106 is at the commanded position and/or if the tube 104 has rotated the amount of rotation determined by the covering position determiner 406 to move the covering 106 to the commanded position. If the rotation is not complete, the example instructions 600 return to block 608. If the rotation is complete (i.e., the covering 106 is at the commanded position or a limit position), the motor controller 412 sends a signal to the motor 120 to stop rotation of the tube 104 (block 612).
The example instructions 700 of
The rotational direction determiner 510 determines the first angular direction (e.g., clockwise) based on movement of the tube 104 determined by the gravitational sensor 126 (e.g., an accelerometer) (block 704). The current sensor 522 determines an amperage of the first signal provided to the motor 120 (block 706). The rotational direction determiner 510 associates the first angular direction with the polarity of the first signal (block 708). For example, the rotational direction determiner 510 associates a positive polarity with a clockwise direction of rotation.
The motor controller 524 of the illustrated example sends a second signal of a second polarity to the motor 120 to cause the tube 104 to move in a second angular direction opposite the first angular direction (block 710). In some such examples, the motor 120 rotates the tube 104 or enables the tube 104 to rotate in the second angular direction (e.g., the motor 120 applies a torque less than a torque applied by the weight of the covering 106 to allow the weight of the covering 106 to rotate the tube 104 to unwind the covering 106). The rotational direction determiner 510 determines the second angular direction (e.g., counterclockwise) based on movement of the tube 104 determined by the gravitational sensor 126 (block 712). The current sensor 522 determines an amperage of the second signal (block 714). The rotational direction determiner 510 associates the second angular direction with the polarity of the second signal (block 716). In the illustrated example, the rotational direction determiner 510 associates the negative polarity with the counterclockwise direction.
The rotational direction determiner 510 determines whether the amperage provided to the motor 120 to move the tube 104 in the first direction is greater than the amperage provided to the motor 120 to move the tube 104 in the second direction (block 718). If the amperage provided to the motor 120 to move the tube 104 in the first direction is greater than the amperage provided to the motor 120 to move the tube 104 in the second direction, the rotational direction determiner 510 associates the first angular direction and the polarity of the first signal with raising the covering 106 (i.e., winding the covering 106 onto the tube 104) (block 720) and associates the second angular direction and the polarity of the second signal with lowering the covering 106 (i.e., unwinding the covering 106 from the tube 104) (block 722). If the amperage provided to the motor 120 to move the tube 104 in the first direction is less than the amperage provided to the motor 120 to move the tube 104 in the second direction, the rotational direction determiner 510 associates the first angular direction and the polarity of the first signal with lowering the covering 106 (block 724) and associates the second angular direction and the polarity of the second signal with raising the covering 106 (block 726). The associations may be stored in the memory 526 to be referenced by the controller 500 when receiving instructions to raise or lower the cover 102.
In the example of
The tube rotational speed determiner 508 of the illustrated example determines whether the tube 104 is rotating (block 804). For example, the gravitational sensor 126 (e.g., an accelerometer) detects movement of the tube 104, and the example rotational speed determiner 508 determines whether the position of the covering 106 is changing over a time imposed with reference to the example clock 504. In some examples, due to a provided dead band (i.e., a lost motion path) when the motor is operatively disengaged from the tube 104, a one-way gear that prevents the motor from driving the tube 104 in the unwinding direction, and/or any other component, the tube 104 stops rotating, at least temporarily, when the covering 106 reaches its lowermost position (e.g., the fully unwound position). If the rotational speed determiner 508 determines that the tube 104 is rotating, the example instructions 800 return to block 802 to continue waiting for the tube 104 to stop rotating, which indicates that the covering 106 has reached its lowermost position.
If the tube 104 is not rotating (block 804), the fully unwound position determiner 512 of the illustrated example determines the position of the tube 104 where the covering 106 is substantially fully unwound (i.e., the fully unwound position) (block 806). For example, when the motor 120 is provided with the signal to lower the covering 106 but the tube 104 is rotated to or past the fully unwound position, the motor 120 drives at least partially through the dead band. As a result, the tube 104 does not rotate for a time, and the lack of movement of the tube 104 is determined or sensed by the gravitational sensor 126 and the tube rotational speed determiner 508. Based on the signal sent to the motor 120 and the lack of movement of the tube 104 while the motor 120 drives through the dead band, the fully unwound position determiner 512 determines that the tube 104 is in the fully unwound position.
The programming processor 516 sets and stores the fully unwound position (block 808). In some examples, the fully unwound position is stored in the example information storage device 526 as a position of zero revolutions. In other examples, the fully unwound position is stored in the example information storage device 526 as a position relative to one or more frames of reference (e.g., a reference axis of the gravitational sensor 126, a previously determined fully unwound position, etc.). In some such examples, the fully unwound position is adjusted based on the one or more frames of reference.
In some examples, the covering position monitor 514 determines other position(s) of the tube 104 relative to the fully unwound position during operation of the example architectural opening covering assembly 100. For example, when the tube 104 is moved, the covering position monitor 514 determines a count of revolutions of the tube 104 in the winding direction away from the fully unwound position based on rotation information provided by the example gravitational sensor 126.
In some examples, after the fully unwound position is stored, the tube 104 is rotated one or more revolutions from the fully unwound position in the winding direction to reduce the strain of the covering 106 on the fixture that attaches the covering 106 to the tube 104. In such examples, the covering position monitor 514 determines or detects the amount of movement of the tube 104 in the winding direction based on the angular movement information provided by the gravitational sensor 126, and the motor controller 524 sends a signal to the motor 120 to drive the motor 120 in the winding direction.
The following commands and actions are merely examples, and other commands and/or actions may be used in other examples. The example instructions 900 of
If no (i.e., zero) polarity modulations occur in a given window (block 906), the example instructions 900 returns to block 904 to continue monitoring for polarity modulations. If one polarity modulation occurs (block 908), the motor controller 524 sends a signal to the motor 120 to rotate the tube 104 in a first direction (block 910). In some examples, if one polarity modulation occurs and the polarity of the signal modulated from positive to negative, the tube 104 rotates in a direction associated with the negative polarity. In some examples, the polarity of the signal is associated with the unwinding direction or the winding direction using the example instructions 700 of
Then, the covering position monitor 514 determines if the covering 106 is at a first limit position (block 912). In some examples, the first limit position is a predetermined lower limit position such as, for example, a preset lower limit position, the fully unwound position, one revolution away from the fully unwound position in the winding direction, an upper limit position, or any other suitable position. The example covering position monitor 514 determines the position of the covering 106 based on the rotation of the tube 104 relative to the fully lowered position and/or the lower limit position. If the covering position monitor 514 determines that the covering 106 is not at the first limit position, the example instructions 900 return to block 910. If the covering position monitor 514 determines that the tube 104 is at the first limit position, the motor controller 524 causes the motor 120 to stop (block 914). The instructions of
Returning to the NO result of block 908, if two polarity modulations occur (block 916), the motor controller 524 sends a signal to the motor 120 to rotate the tube 104 in a second direction opposite the first direction (block 918). In some examples, if two polarity modulations occur and the polarity modulations from positive to negative to positive within the amount of time, the tube 104 is rotated in a direction associated with the positive polarity (e.g., the winding direction). At block 920, the covering position monitor 514 determines whether the covering 106 is at a second limit position. In some examples, the second limit is a predetermined upper limit position. If the covering 106 is not at the second limit position, the example instructions 900 returns to block 918 to wait for the tube 104 to reach the second limit position. If the covering 106 is at the second limit position, the motor controller 524 causes the motor 120 to stop (block 922). As described in greater detail below, the user may set the lower limit position and the upper limit position via a programming mode.
If three polarity modulations occur (block 923), the motor controller 524 sends a signal to the motor 120 to rotate the tube 104 to an intermediate position corresponding to an amount of time that passed between the second polarity modulation and the third polarity modulation (block 924). For example, the amount of opening may be indicated by an amount of time between 0 and 1 second. For example, if the amount of time between the second polarity modulation and the third polarity modulation is about 400 milliseconds, the motor controller 524 sends a signal to the motor 120 to rotate the tube 104 to a position corresponding to a position a distance of about 40 percent of a distance between the lower limit position and the upper limit position (i.e., the covering 106 is about 40 percent open). In some examples, amount of opening of the covering 106 that is desired and, thus, the amount of time in the command, corresponds to an amount of sunlight shining onto a side of a building in which the example architectural opening covering assembly 100 is disposed. For example, the input device 138 may include a light sensor to detect and measure light shining onto the side of the building, and the covering 106 will be opened further when there is less light and will be closed further when there is more light.
If four polarity modulations occur (block 926), the motor controller 524 sends a signal to the motor 120 to rotate the tube 104 to a predetermined position (block 928). In some examples, the predetermined position is an intermediate position between the lower limit and the upper limit. If the number of polarity modulations within the amount of time is greater than four, the example programming processor 516 causes the example controller 500 to enter a programming mode (block 930). As described in greater detail below, a user may set position limits using the input device 138 while the controller 500 is in the programming mode.
Because the gravitational sensor 126 determines tube position information and/or angular positions of the tube 104, the gravitational sensor 126 may be used to sense any manual input that causes the tube 104 to rotate and/or affects rotation of the tube 104 (e.g., speed of the rotation, direction of the rotation). In some examples, if the covering 106 is lifted, pulled, or contacts an obstruction (e.g., a hand of a user, a sill of an architectural opening, etc.), the tube 104 rotates, the tube 104 rotates at a speed different than the speed at which the motor 120 is to drive the tube 104, and/or the tube 104 rotates in a direction different than the direction in which the motor 120 is to rotate the tube 104. In some examples, operation of the input device 138 (e.g., a cord drivable actuator) rotates and/or affects rotation of the tube 104. Thus, based on the angular positions of the tube 104 determined via the gravitational sensor 126, the direction of rotation of the tube 104 determine by the tube directional determiner 510, and/or the speed of rotation of the tube 104 determined by the tube rotational speed determiner 508, the manual instruction processor 518 may determine that a manual input is occurring.
The example instructions 1000 of
If no manual countermand is provided (block 1006), the motor controller 524 sends a signal to the motor 120 to cause the tube 104 to move to a commanded position (block 1008). In some examples, the commanded position is the lower limit position, the upper limit position, or any other set position such as, for example, an intermediate position between the upper limit position and the lower limit position. The example instructions then returns to block 1202.
If a manual countermand is being provided (block 1006), the motor controller 524 sends a signal to stop the motor 120 (block 1010). Thus, the manual input may countermand or cancel the command from the motor controller 524. The example instructions then returns to block 1002.
Returning to block 1004, if the motor 120 is not moving the tube 104 (i.e., a manual input is moving the tube 104), the covering position monitor 514 determines whether the manual input is moving the covering 106 past a limit (block 1012). For example, a user may provide a manual input to rotate the tube 104 to move the covering 106 past the lower limit position or the upper limit position. In such examples, the covering position monitor 514 determines the position of the covering 106 relative to the lower limit position and/or the fully unwound position. In some examples, the current sensor 522 determines an amperage of the current supplied to the motor 120 to determine whether the tube 104 is rotating to move the covering 106 past the upper limit position. For example, if the covering 106 fully winds around the tube 104, an end of the covering 106 may engage a portion of the example architectural opening covering assembly 100, which causes the amperage supplied to the motor 120 to increase. In such examples, if the motor controller 524 determines that the increase in the amperage has occurred, the motor controller 524 determines that the tube 104 is rotating to move the covering 106 past the upper limit position. In other examples, if the manual input moves the covering 106 past the upper limit by a predetermined amount (e.g., one half of a rotation or more), the example controller 500 again determines the fully unwound position using, for example, the example instructions 800 of
If the manual input is moving the covering 106 past the limit (block 1012), the motor controller 524 sends a signal to the motor 120 to drive the motor 120 in a direction opposite of the movement of the tube 104 caused by the manual input (block 1014). For example, if the manual input is moving the covering 106 past the lower limit position, the motor controller 524 sends a signal to the motor 120 to drive the tube 104 in the winding direction. The manual instruction processor 518 again determines whether the user is providing a manual input causing the covering 106 to move past the limit (block 1016). If the user is not providing a manual input causing the covering 106 to move past the limit, the motor controller 524 sends a signal to the motor 120 to stop (block 1018), and the example instructions returns to block 1002. Accordingly, the tube 104 is prevented from rotating to move the covering 106 past the limit.
Returning to block 1012, if the manual input is not moving the covering 106 past the limit, the manual instruction processor 518 determines whether the manual input has rotated the tube 104 a threshold amount (block 1020). In some examples, the threshold amount corresponds to at least a number of tube rotations. In some such examples, the threshold amount is at least a quarter of one revolution. In some examples, the manual instruction processor 518 determines whether the manual input is provided for a continuous amount of time (e.g., at least two seconds). In other examples, the manual instruction processor 518 determines whether the manual input is provided for a total amount of time such as, for example, two seconds within a threshold period amount of time such as, for example, 3 seconds. In some examples, the manual instruction processor 518 determines the amount of time the manual input is provided in only a first direction or a second direction. In some examples, the manual instruction processor 518 determines whether the manual input is equal to or greater than a threshold distance in the first direction or the second direction within the threshold amount of time.
If the manual instruction processor 518 determines that the manual input is not provided for a threshold amount of time or distance, the example instructions returns to block 1002. If the manual input is provided for the threshold amount of time or distance, the motor controller 524 sends a signal to the motor 120 to move the tube 104 in a direction corresponding to the movement of the tube 104 caused by the manual input (block 1022). For example, if the manual input causes the covering 106 to rise, the motor controller 524 sends a signal to the motor 120 to cause the motor 120 to drive the tube 104 in the winding direction. The covering position monitor 514 determines whether the covering 106 is at the limit (block 1024). If the covering 106 is not at the limit, the example instructions return to block 1002. If the covering 106 is at the limit, the manual instruction processor 518 determines whether the manual input is causing the covering 106 to move past the limit (block 1016). If the manual input is causing the covering 106 to move past the limit, the motor controller 524 sends a signal to the motor 120 to drive the tube 104 in the direction opposite of the movement caused by the manual input (block 1014). If the manual input is not causing the covering 106 to move past the limit, the motor controller 524 causes the motor 120 to stop (block 1018), and the example instructions returns to block 1002.
The example instructions 1100 of
In response to the command from the input device 138, the motor controller 524 sends a signal to the motor 120 to move the covering 106 toward a lower limit position (e.g., a previously set lower limit position, the fully unwound position, one revolution of the tube 104 from the fully unwound position in the winding direction, etc.) (block 1106). In some examples, the manual instruction processor 518 continuously determines whether a manual countermand has occurred while the covering 106 is moving. For example, a manual countermand may be provided via a user. If the manual instruction processor 518 determines that a manual countermand occurred, the motor 120 is stopped. If the manual instruction processor 518 determines that no manual countermand occurred, the motor 120 is stopped when the covering 106 is at the lower limit position (block 1108). In other examples, the manual instruction processor 518 does not continuously determine whether a manual countermand occurs while the covering 106 is moving, and the motor 120 is stopped when the covering 106 is at the lower limit position.
The covering position monitor 514 determines positions of the covering 106 (block 1110). For example, after the covering 106 is stopped at the lower limit position, the user may rotate the tube 104 via the input device 138 (e.g., to a desired position), and the covering position monitor 514 determines positions of the covering 106 relative to the fully unwound position and/or the lower limit position based on the angular positions of the tube 104 detected by the gravitational sensor 126. The programming processor 516 determines whether a programming signal is received from the input device 138 (block 1112). In some examples, the programming processor 516 determines whether a signal sent from the input device 138 is a programming signal using the example instructions 900 of
If the programming signal is received from the input device 138, the programming processor 516 sets a lower limit position (block 1116). In such examples, the lower limit position is a position of the covering 106 when the programming signal was received at block 1112. The input device causes an indication to be provided (block 1318).
Continuing to
After the covering 106 moves to the upper limit position, the covering position monitor 514 determines positions of the covering 106 (block 1202). For example, after the covering 106 is stopped at the upper limit position, the user may move the covering 106 via the input device 138 (e.g., to a desired position), and the covering position monitor 514 determines positions of the covering 106 relative to the fully unwound position, the lower limit position, the upper limit position, etc.
The programming processor 516 determines whether a programming signal is received from the input device 138 (block 1204). If the programming processor 516 determines that the programming signal is not received, the programming processor 516 determines whether a threshold amount of time has elapsed (e.g., since the covering 106 moved to the upper limit position) (block 1205). If the threshold amount of time has not elapsed, the example instructions return to block 1202. If the threshold amount of time has elapsed, the programming processor 516 causes the controller 500 to exit the programming mode (block 1206). In some examples, the threshold amount of time is thirty minutes.
If the programming signal is received from the input device 138, the programming processor 516 sets an upper limit position (block 1208). The input device 138 causes an indication to be provided (block 1210).
Continuing to
After the covering 106 moves to the intermediate position, the covering position monitor 514 determines positions of the covering 106 (block 1302). For example, after the covering 106 is stopped at the intermediate position, the user may move the covering 106 via the input device 138 (e.g., to a desired position), and the covering position monitor 514 determines positions of the covering 106 relative to the fully unwound position, the lower limit position, the upper limit position, etc.
The programming processor 516 determines whether a programming signal is received from the input device 138 (block 1304). If the programming processor 516 determines that the programming signal is not received, the programming processor 516 determines whether a threshold amount of time has elapsed (e.g., since the covering 106 was moved to the intermediate position) (block 1305). If the threshold amount of time has elapsed, the programming processor 516 causes the controller 500 to exit the programming mode (block 1306). If the programming processor 516 determines that the threshold amount of time has not elapsed, the example instructions return to block 1302. In some examples, the threshold amount of time is thirty minutes.
If the programming signal is received from the input device 138, the programming processor 516 sets and stores an intermediate position (block 1308). The input device 138 causes an indication to be provided (block 1310), and the programming processor 516 causes the controller 500 to exit the programming mode (block 1312). In some examples, the programming mode is used to set one or more other positions.
The processor platform 1400 of the instant example includes a processor 1412. For example, the processor 1412 can be implemented by one or more microprocessors or controllers from any desired family or manufacturer.
The processor 1412 includes a local memory 1413 (e.g., a cache) and is in communication with a main memory including a volatile memory 1414 and a non-volatile memory 1416 via a bus 1418. The volatile memory 1414 may be implemented by Synchronous Dynamic Random Access Memory (SDRAM), Dynamic Random Access Memory (DRAM), RAMBUS Dynamic Random Access Memory (RDRAM) and/or any other type of random access memory device. The non-volatile memory 1416 may be implemented by flash memory and/or any other desired type of memory device. Access to the main memory 1414, 1416 is controlled by a memory controller.
The processor platform 1400 also includes an interface circuit 1420. The interface circuit 1420 may be implemented by any type of interface standard, such as an Ethernet interface, a universal serial bus (USB), and/or a PCI express interface.
One or more input devices 1422 are connected to the interface circuit 1420. The input device(s) 1422 permit a user to enter data and commands into the processor 1412. The input device(s) can be implemented by, for example, a keyboard, a mouse, a touchscreen, a track-pad, a trackball, isopoint, a button, a switch, and/or a voice recognition system.
One or more output devices 1424 are also connected to the interface circuit 1420. The output devices 1424 can be implemented, for example, by display devices (e.g., a liquid crystal display, speakers, etc.).
The processor platform 1400 also includes one or more mass storage devices 1428 (e.g., flash memory drive) for storing software and data. The mass storage device 1428 may implement the local storage device 1413.
The coded instructions 1432 of
From the foregoing, it will appreciate that the above disclosed instructions, methods, apparatus and articles of manufacture enable one or more architectural opening covering assemblies to be controlled by simply pulling on or otherwise applying force to the covering. The example architectural opening covering assemblies disclosed herein include a gravitational sensor to determine a position of an architectural opening covering, detect an input applied to the covering (e.g., by moving the covering by hand) and/or monitor movement of the covering based on gravity and/or movement relative to a gravity reference. In some examples, the gravitational sensor determines angular positions of a roller tube on which the covering is at least partially wound. In some examples, the gravitational sensors are used to determine if a manual input (e.g., a pull on the covering, operation of an device, etc.) is provided. In some instances, in response to the manual input, an example controller controls the motor to perform the action instructed by the input (e.g., to move the covering, stop movement of the covering, and/or counter the manual input to prevent lowering or raising the architectural opening covering past a threshold position such as, for example, a lower limit position or an upper limit position, etc.).
Although certain example methods, apparatus and articles of manufacture have been described herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus and articles of manufacture fairly falling within the scope of this patent.
This patent claims the benefit of U.S. Provisional Application Ser. No. 61/744,756, titled “Methods and Apparatus to Control an Architectural Opening Covering Assembly,” filed Oct. 3, 2012, which is hereby incorporated by reference herein in its entirety.
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