An automated safety device is described for operational control of a knob on a stove or range and, more particularly, a safety device and method is described for automatically positioning an operational shaft, such as for a burner, to an Off position for terminating power to the burner upon the occurrence of a safety event.
A large number of residential and commercial fires originate in the kitchen during cooking. The stove top burner is a common source for ignition of these fires, for example, as overheated cooking oils or greases can easily ignite. The risks of a fire igniting are significantly higher during unattended use of a stove or range oven. One way to reduce damage of a fire caused by a stovetop burner is to shut off the power to the burner when the fire starts. However, if no one is present, the stove or burner cannot be manually shut off.
For the foregoing reasons, there is a need for a safety device for automatically rotating an operational shaft of a burner to an Off position upon the occurrence of a safety event for shutting off power to the burner. Various sensors and detectors may be provided for detecting abnormal, emergency, or hazardous operating conditions, which may comprise a safety event. In particular, the system may be regulated by at least a motion detector, which senses the presence or absence of a user and, in the latter case, actuates the safety device to turn the operational shaft of the burner to the Off position. In some example embodiments, the device is configured to be incorporated by manufacturers directly into a new burner control apparatus without changing its appearance or operating procedures. In other examples, the device can be retrofitted to existing or already manufactured burner controls.
In one example, a device for operational control of a burner is provided. The device comprising: a fixed base member, a motor member configured to be attached to an operational shaft of the burner, and a controller configured to control rotation of the motor member to cause rotation of the operational shaft of the burner in response to a signal caused by a sensor.
In some examples, the motor member comprises: a gear train configured to engage the fixed base member, and a motor connected to the gear train. The controller is configured to control rotation of the motor to turn the gear train and cause rotation of the operational shaft of the burner in response to a signal caused by the sensor.
In some examples, the motor member comprises a straight drive motor connected directly to the operational shaft of the burner. In some examples, the straight drive motor comprises a gimbal motor.
In some example embodiments, the device further comprises a rechargeable power source comprising a rechargeable battery, and a recharging mechanism configured to recharge the rechargeable battery. In some examples, the recharging mechanism comprises a wireless charging receiver. The recharging mechanism may also comprise a solar panel.
In some example embodiments, the device further comprises a shaker motor configured to provide haptic or tactile feedback. The shaker motor may be configured to activate if the device is touched by a user.
In some example embodiments, the device further comprises a housing member to form a knob.
In some examples, the motor member is configured to be removably attached to the operational shaft of the burner. In some examples, the burner and the operational shaft of the burner were not originally manufactured to include the removably attached motor member and fixed base member.
In some examples, the motor member is integrated with the operational shaft of the burner. The burner and the operational shaft of the burner may be manufactured to include the integrated motor member and fixed base member.
In some example embodiments, the burner is part of a plurality of burners comprising one of a stove, a range, and an oven.
In some example embodiments, the device provides operational control of one of a plurality of burners, wherein each burner of the plurality of burners is associated with a device for operational control of the burner. In some example embodiments, the burner is a single burner.
In some example embodiments, the device further comprises a knob adapter member attached to a top of the device, wherein the adapter member is configured to attach a top knob to the device. In some examples, the knob adapter member further comprises a first magnet attached to the top of the device and configured to magnetically attach the top of the device to one or more of a second magnet or a ferromagnetic material attached to the bottom of the top knob, such that the top knob is configured to be magnetically attached to the top of the device.
In some examples, the knob adapter member further comprises a first ferromagnetic material attached to the top of the device and configured to magnetically attach the top of the device to a magnet attached to the bottom of the top knob, such that the top knob is configured to be magnetically attached to the top of the device. In some examples, the knob adapter member further comprises a first magnet attached to the top of the device and a second magnet attached to a bottom of the top knob, such that the top knob is configured to be magnetically attached to the top of the device.
In some example embodiments, the knob adapter member is configured to prevent rotation of an attached top knob. In some examples, the knob adapter member comprises teeth configured to interlock with corresponding teeth of the attached top knob to prevent rotation of the attached top knob.
In some examples, the knob adapter member is structured to mimic an attachment part of the operational shaft, such that the top knob can be attached to the top of the device. The top knob may also comprise an original knob for operational control of the burner.
In some examples, the controller is configured to cause the motor member to turn the operational shaft of the burner to an Off position. In some examples, the controller is configured to receive the signal and turn the burner to the Off position in response to the signal. In some examples, the signal is a hazard detected signal.
In some example embodiments, the hazard detected signal can be transmitted to the device by a sensor/relay device comprising the sensor, wherein the hazard detected signal is transmitted in response to an occurrence of a safety event, and wherein the occurrence of the safety event comprises one or more of: elapsed no motion time; smoke detection; flammable gas detection; fire detection; remote location detection; and carbon monoxide detection.
In some example embodiments, the signal is an off signal. In some examples, the off signal is received by the device from a sensor/relay device. In some examples, the off signal is received by the device in response to a user off action.
In some example embodiments, the controller receives a timer expiration signal from a timer when an expiration time of the timer elapses, wherein the controller is configured to cause the motor member to turn the operational shaft of the burner to the Off position when the controller receives the timer expiration signal.
In some example embodiments the controller comprises a timer with an expiration time, wherein the controller is configured to start the timer and cause the motor member to turn the operational shaft of the burner to the Off position when the timer expires. In some examples, the controller is configured to restart the timer in response to a restart signal. In some examples, the restart signal is received from a sensor/relay device, wherein the restart signal indicates human motion was detected. In some examples, the restart signal is received from a sensor/relay device, wherein the restart signal indicates a user selection to restart the timer.
In some example embodiments, the sensor comprises a motion sensor, wherein the restart signal is received from the motion sensor of the device, wherein the restart signal indicates human motion was detected.
In some example embodiments, the device further comprises a touch button, wherein the restart signal is received from the touch button of the device, wherein the restart signal indicates that a user touched the touch button of the device. In some examples, the sensor comprises a motion sensor, and wherein the restart signal is transmitted from a motion sensor of the device. In some examples, the expiration time is one of five, ten, fifteen, twenty, twenty-five, thirty, thirty-five, forty, forty-five, fifty, fifty-five, or sixty minutes.
In some example embodiments, the device further comprises a top light positioned to emit light from a top portion of the device. In some examples, the top light comprises an array of light emitting diodes (LEDs). In some examples, the top light is configured to emit light corresponding to a position of the device, wherein the position of the device corresponds to a position of the operational shaft of the burner. In some examples, the top light is configured to emit light in a plurality of segments. In some examples, the top light is configured to emit light in four quadrants, wherein a first quadrant emits light corresponding to a selection of a first user selection; wherein a second quadrant emits light corresponding to a selection of a second user selection, a third quadrant emits light corresponding to a selection of a third user selection, and wherein a fourth quadrant emits light corresponding to a selection of a fourth user selection.
In some examples, the first user selection, the second user selection, the third user selection, and the fourth user selection comprise a user selection of an expiration time for a timer.
In some example embodiments, the device with top lights further comprises a bottom light positioned to emit light from a bottom portion of the device. In some examples, the bottom light comprises an array of light emitting diodes (LEDs).
In some example embodiments, the device further comprises a bottom light positioned to emit light from a bottom portion of the device. In some examples, the bottom light comprises an array of light emitting diodes (LEDs). In some examples, the bottom light is configured to emit light corresponding to an operational status of the device, wherein the operational status comprises at least one of: a device off status; a device on status; a burner on status; a timer expiration status; a hazard detected status; and a device error.
In some examples, the controller is configured to modulate the power supplied to the burner by causing the motor member to turn the operational shaft of the burner to one of a plurality of On positions.
In some examples, the controller is configured to modulate the power supplied to the burner in response to receiving a control signal from a user device.
In some examples, the controller is configured to modulate the power supplied to the burner in response to receiving a control signal from a cooking device.
In some examples, the plurality of On positions includes at least a low position, a medium low position, a medium position, a medium high position, and a high position.
In some examples, the fixed base member is configured to be affixedly mounted, surrounding the operational shaft of the burner, to a surface of a stove, range, or oven of the burner.
In some example embodiments a system for operational control of a burner is provided. In some examples the system comprises a safety device module comprising: a fixed base member; a motor member configured to be attached to an operational shaft of the burner and comprising a motor; and a controller configured to control rotation of the motor to cause rotation of the operational shaft of the burner. The system also comprises a sensor/relay module comprising: one or more sensors configured to generate one or more monitoring signals; a processor, wherein the processor receives the one or more monitoring signals and generates one or more control signals; and a communication unit configured to transmit the one or more control signals to the controller, wherein the controller is configured to interpret the control signals to control rotation of the motor to cause rotation of the operational shaft of the burner.
In some examples, the motor member of the safety device module further comprises a gear train configured to engage the base member, wherein the motor is connected to the gear train, and wherein rotation of the motor causes rotation of the gear train to cause rotation of the operational shaft of the burner.
In some examples, the motor member is configured to be removably attached to the operational shaft of the burner. In some examples, the burner and the operational shaft of the burner were not originally manufactured to include the removably attached motor member and fixed base member. In some examples, the motor member is integrated with the operational shaft of the burner. In some examples, the burner and the operational shaft of the burner are manufactured to include the integrated motor member and fixed base member.
In some examples, the burner is part of a plurality of burners comprising one of a stove, a range, and an oven. In some examples, the safety device module provides operational control of one of a plurality of burners, wherein each burner of the plurality of burners is associated with a safety device module for operational control of the burner.
In some examples, the burner is a single burner.
In some example embodiments, the system further comprises, a knob adapter member attached to a top of the safety device module, wherein the adapter member is configured to attach a top knob to the safety device module. In some examples, the knob adapter member is structured to mimic an attachment part of the operational shaft, such that the top knob can be attached to the top of the safety device module. In some examples, the top knob comprises an original knob for operational control of the burner. In some examples, the controller is configured to cause the motor to turn the operational shaft of the burner to an Off position.
In some examples, the controller is configured to receive one or more control signals from the communication unit and turn the burner to the Off position in response to the control signal.
In some examples, the processor of the sensor/relay module is further configured to determine from the monitoring signals that a safety event has occurred and generate a hazard detected control signal.
In some examples, the hazard detected control signal is transmitted by the communication unit to the controller, and wherein determining from the monitoring signals that a safety event has occurred comprises determining, by the processor, from the monitoring signals that one or more of: elapsed no motion time; smoke detection; flammable gas detection; fire detection; remote location detection; and carbon monoxide detection has occurred.
In some examples, the control signal is an off signal.
In some examples, the controller receives a timer expiration signal from a timer when an expiration time of the timer elapses, wherein the controller is configured to cause the motor to turn the operational shaft of the burner to the Off position when the controller receives the timer expiration signal.
In some examples, the controller comprises a timer with an expiration time, wherein the controller is configured to start the timer and cause the motor to turn the operational shaft of the burner to the Off position when the timer expires.
In some examples, the controller is configured to restart the timer in response to a restart signal. In some examples, the restart signal is received from the sensor/relay module, wherein the restart signal indicates human motion was detected. In some examples, the restart signal is received from the sensor/relay module, wherein the restart signal indicates a user selection to restart the timer.
In some example embodiments, the safety device module further comprises a motion sensor, wherein the restart signal is received from the motion sensor of the safety device module, wherein the restart signal indicates human motion was detected.
In some examples, the safety device module further comprises a touch button, wherein the restart signal is received from the touch button of the safety device module, and wherein the restart signal indicates that a user touched the touch button of the safety device module.
In some examples, the one or more sensors of the sensor/relay module comprises a motion sensor, and wherein the restart signal comprises a control signal generated by the processor and received at the controller from the communication unit.
In some examples, the safety device module further comprises: a top light positioned to emit light from a top portion of the safety device module. In some examples, the top light comprises an array of light emitting diodes (LEDs). In some examples, the top light is configured to emit light corresponding to a position of the safety device module, wherein the position of the safety device module corresponds to a position of the operational shaft of the burner. In some examples, the top light is configured to emit light in a plurality of segments. In some examples, the top light is configured to emit light in four quadrants, wherein a first quadrant emits light corresponding to a selection of a first user selection; wherein a second quadrant emits light corresponding to a selection of a second user selection, a third quadrant emits light corresponding to a selection of a third user selection, and wherein a fourth quadrant emits light corresponding to a selection of a fourth user selection. In some example embodiments, the first user selection, the second user selection, the third user selection, and the fourth user selection comprise a user selection of an expiration time for a timer.
In some examples, the safety device module further comprises: a bottom light positioned to emit light from a bottom portion of the safety device module. In some examples, the bottom light is configured to emit light corresponding to an operational status of the system, wherein the operational status comprises one of: a system off status; a system on status; a burner on status; a timer expiration status; a hazard detected status; a safety device error; a sensor/relay module error; and a system error.
In some examples, the system further includes a user interface module comprising: user interface circuitry configured to receive a user selection and generate one or more user control signals based on the received user selection; and a user module communication unit configured to transmit the one or more user control signals to the sensor/relay module, wherein the communication unit of the sensor/relay module is further configured to receive the user control signals and transmit the user control signals to the controller, wherein the controller is further configured to modulate the power supplied to the burner by causing the motor to turn the operational shaft of the burner to one of a plurality of On positions in response to the one or more user control signals.
In some examples, the system further includes a cooking module comprising: one or more cooking sensors configured to generate one or more cooking signals; a processor, wherein the processor receives the one or more cooking signals and generates one or more cooking control signals; and a cooking communication unit configured to transmit the one or more control signals to the sensor/relay module, wherein the communication unit of the sensor/relay module is configured to receive the cooking control signals and transmit the cooking control signals to the controller, wherein the controller is further configured to modulate the power supplied to the burner by causing the motor to turn the operational shaft of the burner to a plurality of On positions in response to the one or more cooking control signals.
In some examples, the plurality of On positions include a low position, a medium low position, a medium position, a medium high position, and a high position.
In some examples, the one or more sensors comprises one or more of a motion detector, a smoke detector, a carbon monoxide detector, a humidity sensor, a gas sensor, a fire detector, a flame detector, a camera, and a microphone.
In some examples, the safety device module further comprising: a rechargeable power source comprising a rechargeable battery; and a recharging mechanism configured to recharge the rechargeable battery.
In some examples, the recharging mechanism comprises a wireless charging receiver. In some examples, the recharging mechanism comprises a solar panel. In some examples, the sensor/relay module further comprising: a rechargeable power source comprising a rechargeable battery; and a recharging mechanism configured to recharge the rechargeable battery.
In some examples, the recharging mechanism comprises a wireless charging receiver. In some examples, the recharging mechanism comprises a solar panel.
In another example embodiment, a method for operational control of a burner is provided. The method comprising: receiving a monitoring signal from a sensor; determining whether a parameter of the monitoring signal exceeds a predetermined threshold; and based on the determination that the parameter exceeds the predetermined threshold, sending a control signal to a controller; wherein the controller controls a motor that is connected to an operational shaft of a burner and is configured to cause the motor to turn the operational shaft of the burner in response to the control signal based upon the monitoring signal from the sensor.
In some examples, the control signal is sent to a plurality of controllers, wherein each of the plurality of controllers controls a motor that is connected to an operational shaft of a burner of a plurality of burners. In some examples, the control signal causes the motor to turn the operational shaft of the burner to an Off position.
In some examples, the sensor comprises one of a motion detector, a smoke detector, a carbon monoxide detector, a humidity sensor, a gas sensor, a fire detector, a flame detector, a camera, and a microphone.
In some examples, the method further comprises starting a timer with an expiration time; determining that the timer has expired; and based on the determination that the timer has expired, sending a control signal to the controller.
In some examples, the method further comprises restarting the timer upon determination that human motion is detected.
In some examples, the method further comprises: receiving a user selection from a user interface; determining a user control signal from the user selection; and sending the user control signal to the controller.
In another example embodiment, a non-transitory computer-readable storage medium for operational control of a burner is provided. The non-transitory computer-readable storage medium storing program code instructions that, when executed, cause a computing device to: receive a monitoring signal from a sensor; determine whether a parameter of the monitoring signal exceeds a predetermined thresh-old; and based on the determination that the parameter exceeds the predetermined threshold, send a control signal to a controller; wherein the controller controls a motor that is connected to an operational shaft of a burner and is configured to cause the motor to turn the operational shaft of the burner in response to the control signal based upon the monitoring signal from the sensor.
In some examples, the control signal is sent to a plurality of controllers, wherein each of the plurality of controllers controls a motor that is connected to an operational shaft of a burner of a plurality of burners.
In some examples, the control signal causes the motor to turn the operational shaft of the burner to an Off position.
In some examples, the non-transitory computer-readable storage medium stores further program code instructions that, when executed, cause the computing device to further: start a timer with an expiration time; determine that the timer has expired; and based on the determination that the timer has expired, send a control signal to the controller.
In some examples, the non-transitory computer-readable storage medium stores further program code instructions that, when executed, cause the computing device to further restart the timer upon determination that human motion is detected.
In some examples, the non-transitory computer-readable storage medium stores further program code instructions that, when executed, cause the computing device to further: receive a user selection from a user interface; determine a user control signal from the user selection; and send the user control signal to the controller.
In some examples, the non-transitory computer-readable storage medium stores further program code instructions that, when executed, cause the computing device to further: receive a cooking signal from a cooking module; determine a cooking control signal from cooking signal; and send the cooking control signal to the controller.
For a more complete understanding of the automatic safety device and method, reference is now made to the embodiments shown in the accompanying drawings and described below. In the drawings:
In the following description, certain terminology is used to describe certain features of one or more embodiments of the invention. The term “appliance” refers to any type of electrical and/or mechanical device having a control knob unit which accomplishes some household function, such as cooking, cleaning and entertaining. An appliance includes, but not limited to, a stove, oven, fryer, barbeque, clothes dryer, washing machine, air conditioner, television and radio.
The term “event” or “safety event” refers to any type of emergency or developing emergency including, but not limited to, the detection of a hazard such as detection of smoke, fire, heat, carbon monoxide and gas.
The terms “energy source” and “energy” refer to any source of powering an appliance or other device including, but not limited to gas and electricity.
The terms “control knob”, “control knob unit” and “knob” refer to any type of rotating dial or device for adjusting control settings on an appliance or other device.
The term “operational shaft” refers to a mechanism which is used to control the amount of power, such as gas or electricity, supplied to an appliance or other device, such as a burner of a stove.
The term “control settings” may refer to the flow of electricity or gas to an appliance, a timer, etc.
The terms “detector” and “sensor” refer to a device for detecting the presence of hazardous environmental conditions, including, but not limited to, smoke, gas, carbon monoxide gas, flammable gases (e.g. natural gas and propane), fire, flames, and heat, as well as non-environmental hazardous conditions, such as motion.
The use of the term “processor,” “controller,” or “processing circuitry” may be understood to include a single core processor, a multi-core processor, multiple processors internal to any of the modules/devices described herein, and/or remote or “cloud” processors. A controller should be understood to include a controller or microcontroller and contains one or more processors along with memory and programmable input/output components. The controllers described herein should be understood to utilize the processors and memory of the controllers to execute the software functions described herein.
Although the components of the devices and modules are described in part using functional terminology, it should be understood that implementation of the corresponding functions requires the use of particular hardware. It should also be understood that certain of these components may include similar or common hardware. For example, two sets of circuitry on a device/module may both leverage use of the same processor, network interface, storage medium, or the like to perform their associated functions, such that individual/duplicative hardware is not required for each set of circuitry. Furthermore, the use of the term “circuitry” as used herein with respect to components of the devices/modules therefore includes particular hardware configured to perform the functions associated with the particular circuitry described herein.
The term “circuitry” may also include software that configures operation of the hardware of the modules/devices. In some embodiments, circuitry may include processing circuitry, storage media, network interfaces, input/output devices, and the like.
As described above and as will be appreciated based on this disclosure, example devices employed by various example embodiments described herein may be configured as methods, mobile devices, backend network devices, and the like. Accordingly, embodiments may comprise various means including entirely of hardware or combinations of software and hardware. Furthermore, embodiments may take the form of a computer program product stored on at least one non-transitory computer-readable storage medium having computer-readable program instructions (e.g., computer software) embodied in the storage medium. Any suitable computer-readable storage medium may be utilized including non-transitory hard disks, CD-ROMs, flash memory, optical storage devices, or magnetic storage devices.
It is understood that, although a safety device will be described in detail herein with reference to exemplary embodiments of a stove top knob, a safety device may be applied to, and find utility in, other appliances and power tools. Operational control knobs attached to operational shafts are used in a wide variety of applications involving appliances and power tools such as, for example, washing machines, dryers, and the like. Further, although the safety device will be described in detail herein as embodied in a stove knob safety device where rotating motion of the knob is automatic, it is not intended to be so limited. The safety device may be used in rotary power tools, such as power drills, screw drivers, and the like, and in other appliances such as, for example, mixers and blenders. The safety device may be used in the operation of gas or electric grills, toaster ovens, gas and/or electric space heaters, and gas or electric fireplaces. The safety device may also be configured to interrupt the power supply of any electronic device that may be plugged into a wall outlet or any gas device connected to a gas source. Thus, the present safety device has general applicability to any device controlled by a rotating knob wherein improvements in safety are desired.
It is understood that a conventional stove includes an oven and a range top as a single unit. The range top has a plurality of heating elements, or burners, that are used to provide energy, typically heat, to cook food in cookware, such as pots or pans located externally to the stove. The stove may also refer to stand alone units where the oven is separated from the range top, for example, a double oven or a cooktop range. It is understood that the safety device may operate with a separate oven or separate cooktop as well as a stove. For simplicity of this disclosure, the description generally refers to a stove as the cooking unit. It is understood that the safety device will work equally well with stand-alone cooking units.
It is understood that each of the embodiments of the control knob and safety devices described herein may also incorporate one or more aspects or elements of the other embodiments of control knobs and safety devices described herein.
A first embodiment of a stove knob safety device for operational control of a stove top burner is shown in
The housing 22 of the stove knob safety device 20 includes the base member 24 and the outer member 26 coupled to the base member. The base member 24 (
The bracket 28 is disposed in the housing 22 between the base member 24 and the outer member 26. An outer surface 46 (
The gear train comprises a small gear 52 interengaging a larger concentricity gear 54. Both gears 52, 54 are rotatably disposed on the outer surface 56 (
The electric motor 30 is secured in the mount 50 on the bracket 28. The drive shaft of the motor 30 is connected to the small gear 52 for rotating the gear train. In this arrangement, operation of the motor 30 rotates the gear train which in turn rotates the control knob 36 and the connected operational shaft 38 for the burner 40. In one embodiment, the electric motor is a DC motor powered by one or more batteries located within the housing 22. As shown in
A second embodiment of a safety device for operational control of a stove top burner is shown in
In addition to the features described herein, safety device 400 may include any or all of the features of safety device 20 or safety device 100 described herein. In some examples, safety device 400 may function as a replacement knob or a knob for controlling the operational shaft of a burner. Safety device 400 is connected to an operational shaft 38 of a burner and comprises a housing including a housing member 410, fixed base member 424, and outer members 406, 428, a motor member 420 (
The safety device 400 also includes a two-piece adaptor including chuck adapter 436 and device coupler 432 to connect the safety device (and motor member 420) with an operational shaft 38 of a burner, such as burner 40, via the two-piece adaptor. The chuck adapter 436 and device coupler 432 may be configured such that the safety device is removably attached to the operational shaft 38. In some examples, device coupler 432 is configured to attach motor member 420 to the operational shaft 38 by fitting into the chuck adapter 436.
In one example embodiment, the safety device 400 comprises at least the fixed based member 424, the motor member 420 attached to the operational shaft 38, gear train 452 disposed on the motor member 420, and electric motor 454, such that the motor 454 disposed on the motor member and connected to the gear train 454, and wherein the motor is controlled by a controller 462.
In some embodiments, the chuck adapter 436 may comprise a chuck adapter as shown in
Referring back to
Alternatively, the safety device 400 may include a lid cap 404 in lieu of the knob adapter 402. In some examples, outer member 406 serves as a top piece or a lid for safety device 400, the lid providing access to a battery 414.
The safety device 400 also includes a top light window 408 which may be positioned such that it is attached to the housing member 410 and allows lights from LEDs 416 situated on light board 418 to emit light through the top light window 408 (the top portion of the safety device 400). The safety device 400 also includes a bottom light window 426 which may be positioned such that it is attached to motor member 420 and allows lights from LEDs 460 situated on light board 458 to emit light through the bottom light window 426 (the bottom portion of the safety device 400). In some examples, LEDs 416 and 460 may comprise RGB light emitting diodes.
The safety device 400 also includes touch sensor 412. In some examples, the touch sensor 412 may be a capacitive touch sensor configured to receive input by detecting capacitance, such as from a human finger. The safety device 400 also includes a bearing 430 disposed between the fixed base member 424 and the outer member 428. In some examples the bearing 430 comprises a DryLin bearing. The outer member 428 may be composed of Acrylonitrile butadiene styrene (ABS). The safety device 400 also includes a connecting pad 434 to attach the fixed base member 424 to the stove top 440. In some examples, the connecting pad 434 may be a tape pad such that the fixed base member 424 is not permanently fixed to the stove top 440. In another example, connecting pad 434 may comprise a magnet which may attach fixed base member 424 to a metallic surface, such as a metallic stove top.
In some example embodiments, the LEDs 416 are configured to emit light corresponding to a position of the device, wherein the position of the device corresponds to a position of the operational shaft of the burner. In some examples, the LEDs 416 are configured to emit light in four quadrants, wherein a first quadrant emits light corresponding to a selection of a first user selection; wherein a second quadrant emits light corresponding to a selection of a second user selection, a third quadrant emits light corresponding to a selection of a third user selection, and wherein a fourth quadrant emits light corresponding to a selection of a fourth user selection. The user selection may be made by the user at the touch sensor (button) 412 or the user device 1306. In some examples, the first user selection, the second user selection, the third user selection, and the fourth user selection comprise a user selection of an expiration time for a timer.
In some further example embodiments, LEDs 460 may be configured to emit light corresponding to an operational status of the device, wherein the operational status comprises one of: a device off status, a device on status, a burner on status, a timer expiration status, a device error, and a hazard detected status.
The device 400 also includes touch sensor 412. In some examples, the touch sensor 412 may be a capacitive touch sensor configured to receive input by detecting capacitance, such as from a human finger. The device 400 also includes a bearing 430 disposed between the fixed base member 424 and the outer member 428. In some examples the bearing 430 comprises a DryLin bearing. The outer member 428 may also be composed of Acrylonitrile butadiene styrene (ABS) material. The device 400 also includes a connecting pad 434 to attach the fixed base member 424 to the stove top 440. In some examples, the connecting pad 434 may be a tape pad such that the fixed is member is not permanently fixed to the stove top 440. In another example, connecting pad 434 may comprise a magnet which may attach fixed base member 424 to a metallic surface such as a metallic stove top.
The safety device 400 also includes a spring 422 configured to provide support to the motor member 420 and other components of the device 400. The safety device 400 also includes the battery 414 configured to provide power to the electric motor 454 and LEDS 416 and 460. In some examples, the battery 414 may comprise a rechargeable battery. In some examples, battery 414 may be connected to a recharging mechanism. In some examples, outer pieces 406 and 428 may comprise one or more solar panels configured to serve as a recharging mechanism to battery 414. In some examples, the solar panel may receive ambient or room level light and recharge battery 414. This allows for battery 414 and safety device 400 to function for prolonged periods of time without requiring manual recharging. In another example, the recharging mechanism may comprise a wireless recharging mechanism, such as inductive charging (e.g. the Qi standard). In some examples, the safety device 400 may also comprise a shaker motor to provide haptic or tactile feedback for example when the capacitive touch button is engaged. For example, if a user touches touch sensor 412 the shaker motor may provide tactile feedback by shaking enough to indicate to a user that the safety device 400 has registered the touch. For example, the touch sensor 412 may receive a touch from a user and send a signal to controller 462 that receives the signal from the touch sensor 412 and sends a control signal to the shaker motor to provide the tactile feedback. In a similar manner the safety device 400 may also comprise a speaker for providing auditory feedback, such as in the same way as, and/or at the same time the device provides tactile feedback. For example, the speaker may emit a sound while the shaker motor shakes.
In some examples, the touch sensor 412 may comprise multiple segments or a dividing mesh such that the touch sensor 412 comprises multiple touch areas that may function as multiple buttons. For example, the touch sensor 412 may be divided into four areas such that the user may interact with four buttons. The buttons of the touch sensor 412 may be utilized for differentiated input, such as an input for a timer including resetting/restarting the timer or selecting a timer period or expiration time for the timer. For example, a user may select from a selection of five minute increments such as five, ten, fifteen, or twenty minute increment for the expiration time. The buttons of the touch sensor 412 may also be utilized in entering or leaving a child lock mode of the device. For example, a user may enter in a series of touches on the buttons to enter into (engage) a child lock mode and may also enter the same or a different series of touches to leave (disengage) a child lock mode.
The controller 462 may be also programmable to actuate the electric motor 454 to rotate the safety device 400 and, thus, the operational shaft 38 to the Off position upon the receipt of a signal such as a hazard detected signal indicating the occurrence of a safety event. In some examples, the Off position is determined as the position where the operational shaft may not be turned further in a clockwise or counterclockwise position. This may be indicated as when the motor 464 stalls or cannot turn the operational shaft any further such as indicated by a voltage spike from the motor and measure by controller 462.
In some example embodiments, safety device 400 may also include a gyroscope and accelerometer which are used in combination with controller 462 to provide a position sensing function which indicates the position of the safety device 400. In some examples, the Off position may be recorded or set during an initial set-up or calibration of the device (such as the process using user device 1306 described herein). In some examples, safety device 400 also comprises a switch 474 (
Furthermore, in the same manner as the safety device 20, the safety device 400 may also be configured to selectively automatically shut off the flow of electricity or gas to a burner, such as burner 40, under certain predetermined safety conditions. The safety device 400 may also be regulated by a motion sensor, which may be positioned on the device or remote from the device, such as in a sensor/relay device which monitors the presence of a user near the stove to determine whether or not to activate the powered shut-off mechanism. The system may track the time duration of absences of a user via the motion sensor. If no movement is detected within a predetermined period, the safety device 400 may be automatically activated to turn the operational shaft 38 to the Off position. In the event that the motion sensor of the safety device 400 fails or communication with a sensor/relay device also fails, the timer may be reset by a user input, such as a user touching the touch sensor 412 and/or overriding automatic shut-off due to absence of a user. This provides a failsafe mode for the safety device 400 in an instance where the safety device 400 has lost communication abilities with a sensor/relay device, such as a remote motion sensor. This arrangement also allows full control of the operational shaft 38 of a burner, such as the burner 40. For example, the safety device 400 may be configured to move the operational shaft 38 of the burner 40 to multiple On positions.
Turning now to
As shown in
Referring back to safety device 20 and to
The two-piece adaptor 33 and 34 comprises an inner set-screw portion 33 and an outer universal adaptor portion 34. The inner set-screw portion 33 defines a bore 64 for receiving the operational shaft 38 for the burner 40. A set-screw extends through a threaded hole in the set-screw portion 33 and into the bore 64. The set-screw engages the operational shaft 38 for securing the inner set-screw portion 33 of the two-piece adaptor to the operational shaft 38. The outer surface of the set-screw adaptor has a longitudinal key 66. As shown in
The outer universal adaptor portion 34 is a hollow tubular member configured to be secured at an outer end of the control knob 36. The universal adaptor portion 34 enables the safety device 20 to be used universally compatible with control knobs of many designs and configurations. The universal adaptor portion 34 defines a bore with a contiguous longitudinal slot. The shape of the bore and the slot corresponds to the periphery of the inner set-screw portion 33 such that the key 66 is received in the slot in the universal adaptor portion 34. Thus, the adaptor portions are keyed for rotation together along with the concentricity gear 54.
The control knob 36 is secured to, or engaged with, an operational shaft 38 of the burner 40 for controlling power supply used to operate the burner 40. The control knob 36 may be used to manually operate the burner 40. In other words, the control knob 36 is configured to move as a rotary dial in a manner substantially similar to a traditional stove knob for rotating the operational shaft 38 to activate the associated burner. As shown in
In use, the safety device 20 is configured to be received on an operational shaft 38 of a stove or other appliance. A user may retrofit an existing stove by removing an existing knob from a respective stove burner operational shaft and inserting the safety device 20 thereon. As described above, the base member 24 may be adhesively adhered to the surface of the stove surrounding the operational shaft 38. When cooking is desired, the control knob 36 of the safety device 20 is manually rotated in a traditional manner for controlling an output of power from the stove to activate the burner 40. As shown in
Signals may be sent to and from the sensors using wired or wireless signals, such as data signals or messages. As shown in
In operation, the output of the sensors is continuously monitored. In one example, the one or more sensors, such as sensors 1304a-1304c generate one or more monitoring signals which are transmitted to a processor, such as sensor controller 1304d. In some examples, the processor receives the one or more monitoring signals and generates one or more control signals and causes the communication unit 1304e to transmit the one or more control signals to a controller, such as device controller 1302c, which in turn controls a motor, such as motor 1302f. In some examples, the control signals sent between the device controller 1302c and the motor 1302f are Pulse-width modulation (PWM) signals. The controller, such as device controller 1302c communicates with the sensor/relay module 1304 and sensor controller 1304d, which processes data received from the sensors to selectively transmit command data to a motor 1302f, which may comprise a motor in any of the safety devices described herein. The controller includes a processor having programming for operating the safety device module 1302 and functions substantially as described herein. In some examples, the device controller 1302c receives the sensor signals, determines appropriate command/control signals, and transmits the command/control signals either through a wired or wireless interconnection to the motor 1302f. A safety event is detected when a level of any of the sensors 1304a-1304c is detected that exceeds predetermined thresholds by either sensor controller 1304d or device controller 1302c, the controller, under the control of the system software contained within it, sends a control signal to the motor. The motor automatically drives the safety device module 1302 to turn off a burner by rotating the operational shaft of the burner.
Control of the safety device module 1302 may also be communicated by the user through user interface components as part of the safety device module. The interface components that may be a part of the safety device module 1302 as shown in
The system 1300a may further include a selectable timer. The timer may be automatically activated and in two-way communication with a controller 1304c and 1302d. In some examples, the timer will remind the user after a predetermined time that the burner is still activated. In some examples, a speaker may be situated on a printed circuit board and in electrical contact with a controller and the timer. After a predetermined time, the controller in communication with the timer actuates the speaker to emit a sound, such as a chime, for reminding a user to monitor the status of the cooking that was previously initiated. The motion sensor 1304c may also function with a timer. The motion sensor 1304c can have a variable placement location and peripheral view to detect the presence of a user in a predetermined proximity of the burner and can employ different types of sensing mechanism, such as infrared, ultrasound, optical, or weight-sensing switches. After a burner has been turned on, the motion sensor 1304c continuously monitors the presence of a user near the burner. If a user presence is detected, the timer of the safety device module 1302 is bypassed or restarted and power flows to the burner uninterrupted. The safety device module 1302 timer may turn the operational shaft of the burner to an Off position if no user is present and the time since the last user presence is less than a predetermined time. The predetermined time may be reset each time a user presence is detected. However, if no user presence is detected and the predetermined time has elapsed, the controller transmits a command signal to the motor 1302f to turn off the burner. In some examples, motion detector 1304c and sensor controller 1304d are configured to determine if motion detected is human motion. For example, motion sensor 1304c and controller 1304d may be configured to filter out motion caused by inanimate objects, such as shifting light, or things such as pets. For example, motion sensor 1304c and sensor controller 1304d may be configured to detect that sensed motion is from a dog or cat and thus non-human presence has been detected, which may be disregarded or ignored.
In another example, the timer of the safety device module 1302 may be bypassed or restarted by a user utilizing a touch button of the safety device module 1302 or by utilizing a user interface of user device 1306.
As illustrated, each of the safety device module 1302, sensor/relay module 1304, and user device 1306 may be in communication with each other such as through low energy Bluetooth, Wi-Fi, near-field communication (NFC), radio frequency (Rf), or infrared communication among others. The sensor/relay module 1304 may be configured to operate with a plurality of the safety device modules 1302 such as a plurality of safety device modules operating a plurality of burners on a stove top. Similarly, sensor/relay module 1304 may also be in communication with multiple user devices 1306. For example, multiple members of the same household may each use a user device 1306 to communicate with sensor/relay module 1304 and safety device module 1302. In some examples, user device 1306 may connect through a network connection such as an internet or Wi-Fi connection to sensor/relay module 1304 and the sensor/relay module 1304, may connect with safety device module 1302 through low energy Bluetooth, such that communication of system 1300b may use different communication protocols.
In some examples, the user device 1306 may also comprise a Global Positioning System (GPS), such that if the user device leaves a location of the safety device module 1302, the sensor/relay module 1304 and/or the safety device module 1302 may determine that a burner is in an On position representing a hazard detected or safety event. For example, is a user forgets to turn of the burner and leaves their home sensor/relay module 1304 may detect that the user device 1306 is remote from the home and generate a hazard detected signal. In some examples, a user may utilize the user device 1306 interface described herein to override the remote location detection hazard signal in the event that they are aware the burner is still on and would like to leave it on while not in the home.
In some examples, the safety device module 1302 may be embedded into a stove with digital controls such that turning an operation shaft of a burner is not required to turn off power to the burner. In this case, the control signal from the sensor/relay module may indicate to a controller of the safety device to cease providing power by sending a power off signal to a burner control module.
In some examples, a plurality of safety device modules 1302 may be preprogrammed to communicate with a specific sensor/relay module 1304, such that when the modules are powered on they automatically discover and communicate with each other. In other examples, each of a plurality of safety device modules 1302 may enter into a discoverable mode once powered such that a user utilizing user device 1306 and sensor/relay device 1304 may detect the discoverable safety device modules and pair or connect (add) them into the system 1300b. This allows for multiple safety device modules to be connected or replaced at different times.
As shown, the system 1300b may comprise additional safety features to operate safety device module 1302. For example, a child lock or burner use lock may be implemented in system 1300b. A child lock may be implemented to prevent an operational shaft of a burner from being turned to an On position. In some examples, the child lock may include a mechanical lock that prevents a safety device module from being turned from the Off position to an On position.
In one example of the child lock as implement in a safety device module utilizing the safety device 400, the safety device 400 may include an additional child lock member between fixed base member 424 and motor member 420 which may be locked by controller 462 when a child lock has been engaged. A mechanical lock may also be an external piece that may be manually position by a user between the safety device 400 and the stove top. The child lock member may be configured to prevent the engagement of the operational shaft 38 by the motor member 420 preventing the rotation of the safety device 400. In other examples, the controller 462 may include software to automatically turn the operational shaft 38 to an Off positon, preventing the burner 40 from being turned on continuously. For example, a child may manually turn the safety device 400 to an On position, but if the child lock is engaged, the safety device 400 will automatically rotate the operational shaft 38 back to the Off position. Other examples, of a child lock may include locking the electric motor 454 and/or gear train 452. Child lock functions may be engaged using a user interface at the user device 1306 or utilizing user interface components, such as a capacitive touch sensor, at safety device module 1302.
In some example embodiments, the safety device module 1302 may be configured to operate between an appliance 1308 and a power source 1310 as illustrated by example system 1300c in
Referring to
In another example embodiment of system 1300d, a cooking device such as cooking device 1312 may be configured to directly monitor cooking properties, such as temperature, of food or a cooking environment 1314 during the process of cooking food utilizing a burner under operational control of safety device module 1302. The cooking environment 1314 may include a pot, a pan, or any other types of cookware that may use a burner during the cooking process. For example, sous vide is a style of cooking which requires accurate and regulated temperatures of water/steam for long periods of time to properly cook food in this style. Thus, cooking device 1312 may include a thermometer for monitoring the temperature of water/steam in the cooking environment 1314 and may generate a control signal that is used to modulate the power supplied to a burner providing heat to the cooking environment such that a constant regulated temperature is supplied. The control signal may be supplied directly to the safety device module 1302 to modulate the power supplied to the burner or may be sent through sensor/relay module 1304 to safety device module 1302. In another example, cooking device 1312 may include other sensors such as a camera to monitor visual cooking properties, such as color or perceived doneness, of food in the cooking environment 1314, or of the cooking environment 1314, such as the melting of butter or boiling of water. In each of these examples, the cooking device 1312 may include a processor and communication modules in communication with sensor/relay module 1304 and/or safety device module 1302 to control the power supplied to a burner and thus the amount of heat in the cooking environment 1314.
The sensor/relay device 1400 may comprise a housing member 1418, a top piece 1402, and an LED array 1404. The housing member 1418, the top piece 1402, and the LED array 1404 may be attached to base pieces 1410 and 1416 to provide an enclosed sensor/relay device as shown in
Another embodiment of a stove knob safety device for operational control of a stove top burner is shown in the
Referring to
The electric motor 106 is a hollow shaft gimbal motor disposed on the base member 104. The base member 104 has four threaded bosses 117 circumferentially spaced around the opening 116. Threaded fasteners 118 extend through the bosses 117 and into the motor 106 for securing the motor 106 to the base member 104. A coil spring 120 is positioned above the base member 104.
Referring to
As shown in
The knob 36 defines a bore 37 for receiving the spaced distal ends of the arms 133, 134 in a friction-fit relationship. The distance between the arms 133, 134 is adjustable for accommodating different sizes of stove knobs 36. The universal adaptor 110 thus enables the safety device 100 to be used universally compatible with control knobs of many designs and configurations. The control knob 36 is secured to, or engaged with, the operational shaft 38 of the burner 40 through the core unit 108 for controlling power supply used to operate the burner. The control knob may be used to manually operate the burner 40. In other words, the control knob 36 is configured to move as a rotary dial in a manner substantially similar to a traditional stove knob for rotating the operational shaft 38 to activate the associated burner.
In use, the safety device 100 is configured to be received on an operational shaft 38 of the stove or other appliance. A user may retrofit an existing stove by removing an existing knob 36 from a respective stove burner operational shaft and inserting the safety device 100 thereon and then reinserting the knob 36 on the universal adaptor 110. As described above, the base member 104 may be adhesively adhered to the surface of the stove surrounding the operational shaft 38. When cooking is desired, the control knob 36 of the safety device 100 is manually rotated in a traditional manner for controlling an output of power from the stove to activate the burner 40. Upon the occurrence of a safety event, the safety device 100 automatically rotates the control knob 36 to an Off position. More specifically, the motor 106 is started and turns the core unit 108 through the stem 124 which, in turn, rotates the control knob 36 and the operational shaft 38.
Referring to
Referring to
In addition, a squish barrel may also be used as a knob adaptor. A squish barrel may consist of a conical metal price, a cylindrical flexible rubber, and a screw. When the screw is rotated, the conical metal piece advances into the core of the cylindrical flexible rubber. As a result, the cylindrical flexible rubber stretches and expands. When the squish barrel is attached to a stove and the cylindrical flexible rubber is inserted into stem 124 of the knob (as shown in
Referring to
In another preferred and non-limiting embodiment, one or more plastic pieces may be used as a shaft adaptor. To accommodate the shape and size of a particular shaft, a particular plastic piece may be chosen so that the plastic piece can fit into the particular shaft.
Referring to
Example embodiments of rendered user interface components are shown in
Component 2708 represents a highest On position of the operational shaft of the burner, and component 2712 represents a lowest On position of the operational shaft of the burner. Component 2710 represents an Off position of the operation shaft of the burner. In some examples, the user device 1306 may be used to set varying positions of the safety device module during an initial set-up or a calibration of the varying positions. For example, user interface 2702 may include instructions for a user to turn the safety device module to a highest On position such that the operational shaft of the burner is in a highest On position and providing the maximum amount of power (electricity or gas) to the burner. The user may then select that the safety device module 1302 is in the highest On position. User device 1306 may then send a confirmation signal to safety device module 1302 to confirm that the device is in the highest On position. The position may then be stored at controller 1302c for future use by the safety device module. The same process may be used to position the lowest On position, as well as, any number of a plurality of other On positions, such as a medium low position, a medium position, a medium high position, etc., as well as the Off position. Each of the positions may be stored at controller 1302c such that when a control signal is received from user device 1306, the controller may then access the stored position and issue a control signal to the motor such that the operational shaft of the motor will be instructed to turn to the stored position.
Component 2728 represents a user selection of safety device modules each controlling one of a plurality of burners including safety device modules 2728 and 2728a-c. Each of the burners in the plurality of burners may be associated with a safety device module, such as safety device module 1302. A user may be able to independently control the position of each safety device module of the plurality of safety device modules using user device 1306. Components 2720, 2722, 2724, and 2726 may be configured to show other user interfaces corresponding to a presentation of status information of a sensor module such as sensor module 1304, the status of a home, and/or a historical view of the status of the system such as system 1300b. For example, component 2720 may be selected for user interface components related to one or more safety device modules. Component 2722 may be selected for user interface components related to one or more sensor/relay devices. Component 2724 may be selected for user interface components related to one or more elements of a home. Component 2726 may be selected for user interface components related to historical data of the one or more safety device modules, the one or more sensor/relay devices, the home, the user interface components, the user interface, or the user computing device itself. Element 2706 provides access to a settings menu which may allow a user to adjust settings of the user interface, such as an application running on the user computing device 1306 and may also provide support information to the user. Element 2706 may also provide access and management of user account information such as a user name and device information with external server 1320.
In some examples, user device 1306 may receive a notification from safety device module 1302 and/or sensor/relay module 1304 indicating the occurrence of a safety event. In some examples, a user may be able to override the safety device module from turning to the Off position. For example, if a timer has elapsed as described herein, safety device module and/or sensor/relay module 1304 may send a notification with a temporal option to cancel the safety device module 1302 turning to the Off position. The user may also be able to override or temporarily turn one or more of the sensors in the sensor/relay module 1304 off. For example, if a user is cooking and producing large amounts of smoke, but knows there is no fire, the user may utilize user device 1306 to temporality turn off a smoke sensor in the sensor/relay device.
Additionally, user device 1306 may also be configured to allow a user to add multiple authorized users and/or user accounts to control safety device module 1302 and receive device status indications including notifications.
As shown in block 2810 of
In the block 2860 of
Referring to
In operation 2902, safety device module 1302 includes means, such as communication circuitry 1302e, device controller 1302c, or the like, for receiving a monitoring signal from a sensor. In some examples, the monitoring signal may be received from sensors such as a motion sensor located in the safety device module. The sensor may also comprise one or more of a motion sensor, a smoke sensor, a carbon monoxide sensor, a humidity sensor, a gas sensor, a fire detector, a flame detector, a camera, and a microphone. In another example, the monitoring signal may be received by controller 1304d from one or sensors in sensor/relay module 1304, such as any of the sensors 1304a-1304c. For example, smoke sensor 1304a may send a monitoring signal which indicates that a certain level of particulate smoke (a parameter) has been detected by the sensor.
In operation 2904, safety device module 1302 includes means, such as communication circuitry 1302e, device controller 1302c, or the like, and/or the sensor/relay module 1304 includes means, such as communication circuitry 1304e, controller 1304d, or the like, for determining whether a parameter of the monitoring signal exceeds a predetermined threshold. For example, the level of particulate smoke detected by the sensor may be compared to acceptable or predetermined threshold levels, where levels of smoke above the threshold levels may indicate that a hazardous situation or safety event is developing or occurring.
In operation 2906, safety device module 1302 includes means, such as communication circuitry 1302e, device controller 1302c, or the like, for sending a control signal to a controller based on the determination that the parameter exceeds the predetermined threshold. In some examples, the determination that the parameter exceeds the predetermined threshold level may take place at controller 1304d or controller 1302c. In the instance that the determination takes place at 1304d, the controller 1302c may receive an indication of the determination or a control signal from controller 1304d by communication circuitry 1304e and 1302e. The controller 1302c controls a motor, such as motor 1302f, that is connected to an operational shaft of a burner, such as through a gear train. The controller 1302c will then generate or relay a control signal to motor driver 1302d to control motor 1302f. In some examples, the control signal generated by controller 1304d is sent to a plurality of controllers, wherein each of the plurality of controllers controls a motor that is connected to an operational shaft of a burner of a plurality of burners. In some examples, the control signal causes the motor and gear train to turn the operational shaft of the burner to an Off position.
Referring to
In operation 3002, safety device module 1302 includes means, such as device controller 1302c, or the like, for starting a timer with an expiration time. For example, once the operational shaft of the burner has been turned on, the timer may automatically start for a set period expiration time, such as five, ten, fifteen, twenty, thirty, forty-five, or sixty minutes, or any other determined, set, or pre-set length of time.
In operation 3004, safety device module 1302 includes means, such as device controller 1302c, for determining if the timer has expired. For example, after expiration time of five, ten, fifteen, twenty, thirty, forty-five, or sixty minutes has passed, the timer may expire.
In operation 3006, safety device module 1302 includes means, such as communication circuitry 1302e, device controller 1302c, or the like, for sending a control signal to the controller based on the determination that the timer has expired. For example, if the timer is kept by the controller 1302c, the controller may issue or send a signal to itself or merely determine that the timer has expired. The control signal may be an off signal such that the motor that is connected to an operational shaft of a burner through a gear train turns the operation shaft of the burner to an Off position. In some examples, the timer may be kept at sensor/relay module 1304 wherein controller 1304d performs the operation described above and sends the control signal to controller 1302c.
In some examples, the safety device module 1302 includes means, such as device controller 1302c, to restart or reset the timer, such as upon determination that human motion is detected. For example, if human motion is detected by the sensor/relay module 1304 or the safety module 1302 as described herein, the timer may be restarted or reset.
Referring to
In operation 3102, user device 1306 includes means, such as user interface circuitry 1306c, or the like, for receiving a user selection from a user interface.
In operation 3104, user device 1306 includes means, such as device control circuitry 1306e, for determining a user control signal from the user selection. For example, a user control signal may comprise a user selection to modulate the power supplied to control the temperature of the burner.
In operation 3106, user device 1306 includes means, such as communication circuitry 1306d, to send the user control signal to the controller 1302c such that the controller 1302c may cause the motor 1302f to modulate the positon of the operational shaft of the burner.
Referring to
In operation 3202, sensor/relay module 1304 includes means, such as communication circuitry 1304e, or the like, for receiving a cooking signal from a cooking module 1312. For example, cooking module 1312 may determine that the power supplied to the burner needs to be increased and thus transmit an increase temperature cooking signal to the sensor/relay module 1304.
In operation 3304, sensor/relay module 1304 includes means, such as device controller 1304d, for determining a cooking control signal from cooking signal. For example, controller 1304d may determine from the increase temperature cooking signal to modulate the position of safety device module 1302 from a medium position to a medium high position.
In operation 3306, sensor/relay module 1304 includes means, such as communication circuitry 1304e or the like, for sending the cooking control signal to the controller 1302c, where the controller 1302c causes the motor 1302f to modulate the position of the safety device module 1302 and thus modulate the position of the operational shaft of the burner to a medium high position.
Many modifications and other embodiments will come to mind to one skilled in the art to which these embodiments pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that embodiments and implementations are not to be limited to the specific example embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
This application is a divisional application of U.S. Non-Provisional Patent Application Ser. No. 15/639,736, filed Jun. 30, 2017, which claims priority to U.S. Provisional Application No. 62/356,864, filed Jun. 30, 2016, U.S. Provisional Application No. 62/379,671, filed Aug. 25, 2016, U.S. Provisional Application No. 62/404,522, filed Oct. 5, 2016, and U.S. Provisional Application No. 62/447,181, filed Jan. 17, 2017, the entire contents of which are incorporated in their entireties herein by reference.
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20190178502 A1 | Jun 2019 | US |
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Parent | 15639736 | Jun 2017 | US |
Child | 16273492 | US |