The present invention generally relates to remote actuation of a switch and more particularly to actuation of a switch using shape memory alloys, while maintaining the ability to manually actuate the switch.
There are many specialty stores, publications and television programs about home improvement, renovation and construction. As a result, modern consumers are increasingly aware of advancements in technologies relating to the maintenance and operation of their homes. One increasingly popular trend in home technology concerns home automation wherein various devices can be controlled by remote actuation. Remote actuation allows the consumer to control the various devices beyond the reaches of any such device.
Typically, many devices are already controlled by switches and already integrated into the wiring of the building or location. One of the more prevalent examples may be a room light controlled by a conventional switch at the entrance to the room. It will be appreciated that many devices located in buildings or various locations, whether outside or inside, may be already controllable by conventional switches.
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The configuration of the gang box 12 is typically standardized so that many different configurations of the wall switch 10 can be installed into the gang box 12, for example, lever switches, rocker switches, and/or dimmer switches, which may be collectively referred to as switch toggles. Nevertheless, many of the switches 10 generally conform to a set geometry, such that a distance 18 between each of the light switches 10 (one of which is shown) in the gang box 12 is standard and is about two inches (about 50 millimeters). It will be appreciated that if the gang box held more than two of the switches 10, the distance 18 between each of the switches 10 would be about the same.
The mounting plate 14 includes a first pair of apertures 20 and a second pair of apertures 22. The first pair of apertures 20 is configured so that the switch 10 may be secured to the gang box 12 with conventional fasteners 24. The second pair of apertures 22 is configured so that a switch cover (not shown) can be secured to the switch 10 with conventional fasteners (not shown). It will be appreciated that the double gang box 12 is configured to optionally contain two of the switches 10; therefore, the switch cover (not shown) can be configured to attach over two of the switches 10 by inserting conventional fasteners through the switch cover (not shown) into the second set of apertures 22.
The switch 10 may be configured with standard distances between the first pair of apertures 20 and the second pair of apertures 22. As such, the distance between the first pair of apertures 20 is about three and one-quarter inches (about 82 millimeters) and is indicated by reference numeral 26. The distance between the second pair of apertures 22 is about two and one-half inches (about 63 millimeters) and is indicated by reference numeral 28.
The switch lever 16 or switch toggle, in the conventional switch 10, opens and closes a circuit to which the switch 10 can be attached. The switch lever 16 in a first position typically corresponds to an “on” position. The on position refers to the switch 16 closing—thus completing—the circuit to which it is attached and ultimately delivering electricity to a device also on the circuit. The circuit, for example, could be a simple household power source connected to a lamp and the switch 10. The lamp may be plugged into a wall electrical socket that is controlled by the switch 10. With this arrangement, when the switch 10 is on or in the first position, the lamp will be on. When the switch 10 is off or in the second position, the light is turned off. It will be appreciated that when the switch lever 16 is in an up position, it is typically in the on position, which is also defined as the first position. As such, when the switch lever 16 is in a down position, it is typically in the off position, which is also defined as the second position.
The switch lever 16 contains a conventional spring (not shown) within the switch 10. As such, a force need not be applied to the switch lever 16 throughout the entire motion from the first position to the second position. The switch lever 16, therefore, need only be moved approximately 85% from one position toward another, as the spring will complete remaining motion.
The conventional switch 10 can be integrated into many applications such as residential, commercial or industrial buildings. The switch 10 can be electrically connected to many devices. As such, it is desirable to control any such device at a location beyond the reach of its respective switch. It also desirable to maintain the ability to manually actuate the switch 10 when in close proximity to the switch 10.
Implementations of remote switch actuators that are installed over, or in lieu of, conventional household switches have been very bulky and/or difficult to install. Some implementations require the consumer to replace a conventional light switch or cover up the light switch entirely with the remote actuator. Other implementations are configured so that the remote actuator is installed over an existing light switch where the lever extends through the actuator but still does not allow manual actuation of the light switch. The bulkiness of previous implementations has also not been visually appealing to the consumer as the bulkiness manifests itself in the large device extending from the wall.
Other implementations of remote actuators have included rather complex and expensive systems to actuate the light switch. Previous exemplary systems have included worm drive systems and/or various gear assemblies to actuate the light switch. These systems only allow the user to actuate the light switch with the remote control actuator and eliminate the ability to actuate the light switch manually. Other implementations have also resulted in a shorter battery life or the requirement to hardwire the remote actuator into the building electrical system to avoid the short battery life problem.
It is desirable to provide a remote actuation unit that does not rely on complex, bulky, and otherwise expensive gearing assemblies. It is also desirable to provide a slim and visually appealing package for the remote actuation device. It is additionally desirable to maintain the ability for the consumer to manually actuate the switch without regard to the position of the remote actuation device. It is also desirable to provide at least the above functionality and provide substantial battery life.
In one form, the teachings of the present invention provide a device to actuate a switch. The switch has a switch toggle movable between a first position and a second position. The device includes a switch yoke movable between the first position and the second position adapted to engage the switch toggle and move therewith. The device also includes a first linkage connected to the switch yoke. The first linkage applies a force in response to an input signal to move the switch yoke from the first position to the second position. The first linkage includes a shape memory alloy.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description, the appended claims, and the accompanying drawings, wherein:
The following description of the preferred embodiments is merely exemplary in nature and is in no way intended to limit the invention, its application or uses.
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A pair of fasteners 108 can be used to secure the housing 104 to the light switch 106. It will be appreciated that the fasteners 108 may be used to secure the housing 104 to the switch 106 using the second pair of apertures 22 (
A switch yoke 110 may be partially visible through the housing 104. The switch yoke 110 is used to move a switch lever 112 or a switch toggle of the switch 106 from a first position to a second position. It will be appreciated that the first position may correspond with an “on” position of the switch 106 and a second position may correspond to an “off” position of the switch 106. It will be further appreciated that the “on” and “off” positions of the switch 106 are in reference to the conventional household switch 10 (
The transmitter 102 includes a remote transmitter housing 114, a first button 116, a second button 118, a third button 120, a fourth button 122 and a fifth button 124. The aforementioned buttons may be hereinafter collectively referred to as buttons 126. The first button 116 can be configured to control the actuator 100. As such, a user (not shown) may select the first button 116, which in turn will control the actuator 100 to move it from its current position to a new position, for example, if the actuator 100 is in the first position, selection of the first button 116 will control it to the second position. If the actuator 100 is in the second position, selection of the first button 116 will control the actuator 100 to the first position. It should therefore be noted that controlling the actuator 100 from the first position to the second position necessarily encompasses controlling the actuator 100 from the second position to the first position.
Either the first button 116, the second button 118, the third button 120, the fourth button 122 or the fifth button 124 can be configured to control the remote actuator 100. It will be appreciated that multiple remote controlled wall switch actuators 100 can be installed in a given location. If, for example, five actuators 100 were installed in a given location, the buttons 126 of the remote transmitter 102 may be individually assigned to control an associated one of the actuators 100. It will be further appreciated that the individual buttons 126 of the remote transmitter 102 may control multiple actuators 100, for example, the second button 118 may control three actuators 100 at once. In that example, selecting the second button 118 will control the three actuators 100, and if all of the actuators 100 are in the same position, selection of the second button 118 will control the actuators 100 to the other position. It follows that regardless of the position of the actuators 100, selection of the second button 118, in that example, will control the actuators 100 to the opposite position.
Those of ordinary skill in the art will appreciate from the disclosure that two of the buttons may be employed to control one of the actuators 100. For example, the actuator 100 may respond to a signal, which is generated by the transmitter 102 in response to the actuation of button 116, to cause the switch yoke 110 to move the switch lever 112 to the “on” position only if the switch lever 112 is not in the “on” position when the signal is generated. Similarly, the actuator 100 may also respond to a signal, which is generated by the transmitter 102 in response to the actuation of button 118, to cause the switch yoke 110 to move the switch lever 112 to the “off” position only if the switch lever 112 is not in the off” position when the signal is generated.
It will be additionally appreciated that one or more of the buttons 126 can be configured, so that when selected control one or more actuators 100 from the first position to the second position. For example, the fourth button 122 can be configured to turn off all of the actuators regardless of the position of the actuator, such that some actuators may be in the second position and remain in the second position while others may be in the first position and will move to the second position. It follows, therefore, that one or more of the buttons 126 can be configured so that the actuator 100 responds by moving from the second position to the first position, such that some of the actuators may be in the first position and remain in the first position while others may be in the second position and will move to the first position.
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It will be appreciated that the housing 104 may be configured to fit over the single switch or multiple switches. To that end, multiple housings may be attached to multiple switches or a larger housing may be attached to the multiple switches. It will be further appreciated that in applications where the larger housing is used to actuate multiple switches, the power supply, the actuation assembly and the controller module will be modified to accommodate the additional switches.
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On the switch yoke 110, opposite the rounded contact points 138, is a linkage contact point 140. A first linkage 142 connects a first post 144 to the linkage contact point 140. A second linkage 146 connects a second post 148 to the linkage contact point 140. The first linkage 142 and the second linkage 146 are comprised of at least one shape memory alloy wire 150. The first linkage 142 and the second linkage 146 may be comprised of two shape memory alloy wires 150.
The shape memory alloy wire 150 is available from many sources and in many configurations; as such, various compositions and dimensions of the wire 150 may be used in the actuator 100. In the various embodiments, the wire 150 can be a nitinol wire obtained from Dynalloy, Inc (Costa Mesa, Calif.) under the trade name Flexinol®. The wire 150 begins to constrict when heated above its transformation temperature, which is about 194 degrees Fahrenheit (about 90 degrees Celsius). The wire 150 will begin to cool and resort to its relaxed condition when its temperature drops below the transformation temperature.
In the embodiment illustrated, the two wires 150 have a diameter of about 0.008 inches each (about 0.2 millimeters) and apply about 1.3 pounds (about 5.8 Newtons) of force each when they are heated above their transformation temperature. It will be appreciated that thicker wires can be used to apply the same force but inherent in a larger diameter wire is a longer relaxation time, hence a longer cooling time. It will be appreciated that this is due to a smaller ratio of surface area to cross-sectional area, relative to several thinner wires. As such, two thinner wires may apply the same force as a single thicker wire but cool faster, or varying size wires may be used to apply a suitable force with a suitable relaxation time.
The actuator 100 may also include a first position-sensing switch 152 and a second position-sensing switch 154. The switch yoke 110 may be configured to make contact with the first position-sensing switch 152 when the switch yoke 110 is in the first position. In turn, the switch yoke 110 may also be configured to make contact with the second position-sensing switch 154 when the switch yoke 110 is in the second position. It will be appreciated that when the switch yoke 110 is in the first position, the linkage contact point 140 has pivoted away from the first post 144 and that when the switch yoke 110 is in the second position, the linkage control point has pivoted away from the second post 148.
It will be appreciated that the actuator 100 can be manually actuated regardless of the position of the switch yoke 110. It will be further appreciated that manual activation refers to the user moving the switch lever 112 independent of any control of the actuator 100. As such, when the switch lever 112 is moved to a first position, the switch yoke 110 will move to a first position and thus make contact with the first position-sensing switch 152. It follows, therefore, that when the switch lever 112 moves to the second position, the switch yoke 110 makes contact with the second position-sensing switch 154.
Even when the switch 106 is manually actuated, the actuator 100 detects the position of the switch 106. The actuator 100, therefore, when activated will move the switch 106 from its current position to a new position. For example, if the user (not shown) moves the switch 106 to the first position from the second position and then the actuator 100 is activated, the actuator 100 will move the switch 106 from the second position to the first position. It will be appreciated therefore, that the actuator 100 can be used to actuate the switch 106 remotely without any manual actuation of the switch 106. With the actuator 100 installed, the switch 106 can also be used exclusively via manual actuation. The switch 106 can also be actuated manually from the first position to the second position and then return to the first position using the actuator 100. It follows that the actuator 100 can move the switch 106 from the first position to the second position and then the switch 106 can be manually actuated back to the first position.
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In the control module 134, the processor 160 is configured to control the actuator 100. The remote control receiver module 162 is configured to receive radio frequency (RF) transmissions from the remote transmitter 102. It should be appreciated that the remote transmitter 102 is only one type of transmitter that can be used to activate the actuator 100 by sending an input signal. Other such input signals to activate the actuator 100 can be sent from motion sensors, proximity sensors, timers, light sensors or any combination of these devices.
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The processor 160 is connected to the remote control receiver module 162, which may receive the input signals from many sources. Some sources that can send input signals may be, for example, the remote transmitter 102, a timer 172, a light sensor 174 or a motion or proximity sensor 176 all of which can send an input signal via RF communication 178. It will be appreciated that the processor 160 can be configured to receive signals directly from the remote transmitter 102, the timer 172, the light sensor 174, or the motion or proximity sensor 176 or other logic components can be configured to receive the same signals and direct them to the processor 160. Regardless of the source of the input signal, the remote control receiver module 162 responds to the input signal by generating an actuation signal. It will be appreciated, however, that the either the timer 172, the light sensor 174, or the motion or the proximity sensor 176 may be integral to the actuator 100 or may be installed remotely and send signals to the actuator via RF communication 178 or any other suitable form of electromagnetic wave communication. It will also be appreciated that the processor 160 can be configured as a single or multiple integrated circuit controllers or multiple logic components.
The remote control receiver module 162 may also be configured to receive an audio input signal such as a clapping sound or a voice command. It will be appreciated that the actuator may be close enough to a user to receive audio input, but still may be far enough away where manual actuation is not possible. To that end, the actuator 100 can be configured to receive audio inputs and thus generate the actuation signal.
The remote control receiver module 162 may also be configured to receive an input signal through a home automation system, such as through household electrical system using the X10® protocol. The remote control receiver module 162 may also be configured to receive signals from a universal remote control. Integration of the X10® protocol and use of universal remote controls are more fully discussed in commonly assigned U.S. patent application Ser. No. 10/697,795, titled Home Automation system, and filed Oct. 30, 2003, which is hereby incorporated by reference as if fully set forth herein.
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In the various embodiments, this is accomplished by the processor 160 sending a signal to the first latch 164. The first latch 164 activates the first driver 166, resulting in the driver 166 heating the first linkage 142. Heating of the shape memory alloy wires 150 (
Once the switch yoke 110 reaches the second position and makes contact with the second position-sensing switch 154, the processor deactivates the first driver 166. The first driver 166 will remain on until the switch yoke 110 moves into the second position and makes contact with the second position-sensing switch 154, or until a maximum actuation time has elapsed. In the various embodiments, the maximum actuation time can be about one second. If the driver has been on for more than the maximum actuation time and the yoke has not completed the motion from the first to the second position, the processor turns off the driver. The processor will turn off the driver, in this scenario, to prevent possible damage to the actuator 100.
The processor 160, after sending a signal to the first latch 164, will not send any more signals for a predetermined lock-out time. The lock-out time may be about five seconds. The lock-out time may include an actuation time, a shape memory alloy relaxation time and a system delay. The actuation time refers to the time it takes to move the switch yoke between the first position and the second position when the actuator 100 is actuated. The shape memory alloy relaxation time refers to the time it takes for the shape memory alloy wire to cool after being heated. In the particular example provided, the actuation time is about one second, the shape memory alloy relaxation time is about two and one half seconds, and the system delay is about one second. It will be appreciated that changes to the shape memory alloy, system geometry, or various other design changes may necessitate changes to either the actuation time, the shape memory alloy relaxation time or the system delay.
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In the various embodiments, this is accomplished by the processor 160 sending a signal to the second driver 168, which heats the second linkage 146. Heating of shape memory alloy wires 150 (
Once the switch yoke 110 reaches the first position and makes contact with the first position-sensing switch 152, the processor deactivates the second driver 168. The processor 160, after sending a signal to the second driver 168, will not send any more signals for the predetermined lock-out time.
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It will be appreciated that various designs of the components can be incorporated into the processor or configured as separate components. For example, the processor provides, among other things, a timing circuit to turn off and on the driver. One skilled in the art will appreciate that various processors can be configured to provide the functionality of a discrete logic component that functions as a timing circuit. On the other hand, discrete logic components can be configured to accomplish the same task whether or not a processor is utilized.
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In the various embodiments, the remote controlled wall switch actuator can be electrically connected in various ways. In
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On the switch yoke 208, opposite the contact points 214, is a linkage contact point 216. A first linkage 218 connects a first post 220 to the linkage contact point 216. A second linkage 222 connects a second post 224 to the linkage contact point 216. The first linkage 218 and the second linkage 222 are comprised of at least one shape memory alloy wire 226. In the various embodiments, the first linkage 218 and the second linkage 222 are comprised of two shape memory alloy wires 226.
The actuator 200 also includes a first position-sensing switch 228 and a second position-sensing switch 230. The switch yoke 208 is configured to make contact with the first position-sensing switch 228 when the switch yoke 208 is in the first position. In turn, the switch yoke 208 is also configured to make contact with the second position-sensing switch 230 when the switch yoke 208 is in the second position. It will be appreciated that while the configuration of the actuator 200 is different from the actuator 100, many aspects of the functionality remain the same. As such, the actuator 200 can be manually actuated regardless of the position of the switch yoke 208.
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In various embodiments, a first linkage 306 constricts to move the rocker switch 300 to the first position, as shown in
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.
This application is a continuation of U.S. patent application Ser. No. 11/044,552 filed on Jan. 25, 2005. The disclosure of the above application is incorporated herein by reference.
Number | Date | Country | |
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Parent | 11044552 | Jan 2005 | US |
Child | 12115797 | US |