Patent Grant
10925128
A Light Emitting Diode (LED) is an electrical component that emits light when a suitable voltage is applied across its leads. Luminaires may include one or more LEDs in a form factor suitable for various applications. For example, a luminaire may be shaped like an incandescent lightbulb or fluorescent filament to fit the lamps and light fixtures in a home or office. Luminaires may also be designed for use in industrial environments, where caustic chemicals, flammable materials, extreme temperatures, or combinations thereof may be present at a greater frequency than in the home or office. Several industrial standards are in place to ensure that the luminaire does not become a danger in various environments (e.g., provide reactants to caustics, become a flashpoint around flammable materials, warp under temperature). These standards often require pass/fail testing when the tested device is initially constructed, but inherent failure modes of some LED devices may result in unanticipated risks, which may lead to safety related events such as fire and explosion during or after installation.
The present disclosure is directed to systems, devices, and methods for improving the safety of Light Emitting Diode (LED) luminaires through active tuning of the drive current to the LED. By measuring the heat of an LED load with a thermally active electrical component, a current controller may adjust the current running through the components of the LED load, and thereby reduce the heat produced via resistive losses when heat is building up, and allow the LED load to cool to acceptable levels.
The above summary is not intended to describe each aspect or every implementation. A more complete understanding will become apparent and appreciated by referring to the detailed description in conjunction with the accompanying drawings, and that the scope of the present disclosure is set by the claims.
The accompanying drawings, which are incorporated in and constitute a part of this disclosure, illustrate various aspects of the present disclosure. The drawings are not necessarily to scale. Like numbers used in the drawings refer to like components, however, it will be understood that the use of a number to refer to a component in a given drawing is not intended to limit the component in anther drawing labeled with the same number. In the drawings:
Various examples will be described in detail with reference to the drawings, wherein like reference numerals represent like parts and assemblies throughout the several views. Any examples set forth in this disclosure are not intended to be limiting and merely set forth some of the many possible ways for implementing the broad inventive aspects disclosed herein.
A Light Emitting Diode (LED) is an electrical component that converts the energy supplied in electrical current into light via electroluminescence. As will be appreciated, as current runs through (non-superconductive) electrical components, such as LEDs, a portion of the energy in the current is converted to heat via the component's resistance. This heat is radiated to the surrounding components and environment, and may build up in the component, making it hotter, if the energy supplied to the component produces more resistive heat than the component can dissipate in a given period of time. To keep a component within a specified temperature range, heatsinks, fans, cooling ducts, and the like can improve the ability of a component to dissipate heat to the environment, or the current running through a component may be reduced to thereby reduce the heat needed to be dissipated. As will be appreciated, keeping a component or fixture within a given temperature range may improve the safety of the electrical device (e.g., reducing the likelihood that the device may act as an ignition source), the longevity of the components of the fixture (e.g., reducing the likelihood of burning a component out), and help devices meet industrial standards for use in a greater variety of settings (e.g., a luminaire deemed safe for use in a home environment may not meet a safety standard for use in a coal mine without additional heat controls). Moreover, depending on the failure mechanism of the luminaire, when a subset of the device (e.g., a die in a multi-die device) fails, current from the failed portions may be driven through the portions that have not yet failed, which can increase the overall heat in the device (or the operable portions thereof) and can lead to accelerated failure of the still-operable portions and/or safety hazards.
To adapt a luminaire to a hazardous environment, the LEDs may be isolated from the environment by an air-tight casing including a non-reactive material (e.g., silicone or glass) through which the LEDs will shine. The casing may be clear or colored, and may be impact resistant or made of a shatter proof material. Additional heatsinks, arc suppression, and interlock features may also be included so that when the luminaire is active in a hazardous environment, no ignition or reaction sources will be exposed to the environment.
The example LED luminaire 100 is illustrated in two sections; the driving circuit 120, including a current controller 121 and a rectifier 122, and the LED load 130, including a temperature sensor 131 and LEDs 132a-u (generally, LEDs 132). Although both sections are illustrated as being disposed of on the same PCB 110, one of ordinary skill in the art will recognize that the driving circuit 120 and LED load 130 may be disposed of on separate PCBs 110, and that a single driving circuit 120 may be communicated to several LED loads 130.
The driving circuit 120 includes a current controller 121 and a rectifier 122. The current controller 121 controls the level of current provided from an alternating current power source (not illustrated), and the rectifier 122 converts alternating current into direct current for use by the LED load 130. In aspects that use a direct current power source (e.g., a battery) instead of an alternating current power source, the current controller 121 controls the level of current provided from the direct current power source and the rectifier 122 may be omitted or bypassed. In various aspects, the rectifier 122 may be of various configurations and contain components of various values depending on the design specifications and use cases expected of the example LED luminaire 100, and one of ordinary skill in the art will be familiar with the construction of a rectifier 122 to meet the needs of a given LED luminaire 100.
In various aspects, the current controller 121 includes a microprocessor that processes signals according to stored instructions (e.g., burned into the microprocessor, stored as Electrically Erasable Programmable Read-Only Memory (EEPROM)) to affect a level of current provided to the LED load 130. In other aspects, the current controller 121 includes a series of logic gates that control switches that will open and close in response to signals received from the LED load 130 to raise or lower current levels transmitted to the LED load 130. Changes to the level of current provided to the LED load 130 may be accomplished with a dimming functionality, allowing the LED load 130 to produce less light with less current, or with a switching functionality, temporarily cutting off current to an LED load 130 or a portion of the LEDs 132 in an LED load 130. For example, the current controller 121 may temporarily restrict the flow of current to the LEDs 132 (turning them off when current reaches zero or a cutoff for LED operation) until the heat of the LED load 130 drops below a threshold. In another example, a first LED load 130 has its current set to zero until the first LED load 130 cools below a threshold temperature, but a second LED load 130 is provided current. The thresholds may be set via various standards bodies according to various standards (e.g., Underwriters Laboratories (UL), the Institute for Electrical and Electronic Engineers (IEEE), European Conformity (CE), China Compulsory Certificate, (CCC)) for the temperature of the luminaire in-use, which one of ordinary skill in the art will be able to apply.
The LED load 130 includes at least one temperature sensor 131 and at least one LED 132. The temperature sensor 131 is communicated with the current controller 121 so that the temperature of the LED load 130 can be reduced via the regulation of current transmitted to the LED load 130.
In various aspects, the temperature sensor 131 is a thermistor, a thermocouple, a resistance temperature detector (RTD), or an infrared (IR) photodiode. In some aspects, where the resistance of the temperature sensor 131 changes in relationship with temperature, a reference current of a value known to the current controller 121 is fed through the temperature sensor 131 so that the current controller 121 can measure a change in resistance (via changes in voltage across the temperature sensor 131) that indicates a temperature of the LED load 130. In some aspects, the reference current supplied to the temperature sensor 131 may be the operating current of the LEDs 132 that the current controller 121 adjusts to affect the temperature of the LED load 130, while in other aspects a separate current is provided so that if the operating current is modified (or set to zero) the reference current will remain constant.
In aspects where more than one temperature sensor 131 is provided, multiple temperature sensors 131 may be associated with the same LED load 130 or with multiple LED loads 130. The current controller 121 may average the readings from the multiple temperature sensors 131 or use the maximum value received from a temperature sensor 131 when the multiple temperature sensors 131 are on one LED load 130, but will treat the readings from multiple temperature sensors 131 from multiple LED loads 130 separately to manage the heat of each LED load 130 separately. Readings may be averaged by using a shared lead of a microprocessor in communication with multiple analog temperature sensors 131 wired in parallel, a bitwise averaging circuit (e.g., an Adder and a bit-shift register) when using digital temperature sensors 131, or by other means known to those of ordinary skill in the art. Additionally or alternatively, another algorithm besides averaging may be used to collect and smooth cumulative readings over a period of time. Contrarily, readings may be separated by using different leads of a microprocessor (or separate sets of logic gates) to receiving readings.
In some aspects, when an overheat threshold is reached, some or all of the LEDs 132 comprising the LED load 130 may be switched off, the current from the AC power source 150 may be reduced, a secondary string of LEDs 132 may be activated instead of a primary string of LEDs 132, a cooling apparatus (e.g., a fan, a vent, a heat pump) may be provided power, etc. In other aspects, when a cooldown threshold is reached, such as when the actions taken in response to an overheat threshold are deemed effective and the LED luminaire 100 can safely resume normal operations, some or all of the LEDs 132 comprising the LED load 130 may be switched on, a primary string of LEDs 132 may be activated instead of a secondary string of LEDs 132, the current provided from the power source 150 may be increased (up to a nominal value), a cooling apparatus may be turned off, etc.
Method 200 proceeds to OPERATION 220, where heat is monitored. Depending on the number and arrangement of temperature sensors 131, the current controller 121 may measure an average, a maximum, or several temperature readings from the LED load 130. In various aspects, the temperature readings may be polled from the sensors or received in real-time. To prevent spikes in readings, in various aspects the multiple readings from one temperature sensor 131 (or group of related temperature sensors 131) may be averaged over a time period or another algorithm may be applied to adjust the level of current provided to the LED load 130 based on the cumulative temperature data from one or more temperature sensors 131.
These temperature readings are compared to a threshold at DECISION 230 to determine whether the temperature exceeds the threshold. When the reading exceeds a threshold, method 200 proceeds to OPERATION 240. When the reading does not exceed the threshold, method 200 proceeds to DECISION 250.
At OPERATION 240, the operational current is reduced by the current controller 121. As will be appreciated, when the current controller 121 reduces the operational current in steps (e.g., 100% to 75% to 50% to 25% to 0%), multiple temperature thresholds may exist so that the current controller 121 may adjust the operational current in accordance with the steps. Steps may be even (n % steps), or uneven, or set to grow/shrink (e.g., 100% to 90% to 70% to 40% to 0%). When the current controller 121 adjusts the operational current in a continuum according to the temperature sensor 131 (e.g., an analog reading from the temperature sensor 131 produces an analog reduction in the operational current) the threshold may be a cutoff value (voltage or current) before which no adjustments to the operational current will be made.
In various aspects, a cutoff value may be supplied by a diode breakdown or avalanche, switches, or the sensitivity of the current controller 121. Method 200 then returns to OPERATION 220 to continue monitoring the heat of the LED load 130.
In aspects where there are multiple temperature sensors 131 associated with different LED loads 130, the current controller 121 may adjust the current supplied to the LED load(s) 130 so that each LED load 130 is affected individually by an associated temperature sensor 131 (e.g., a first temperature sensor 131 or group thereof affects the current supplied to a first LED load 130), is affected mutually by an unassociated temperature sensor 131 (e.g., a second temperature sensor 131 associated with a second LED load 130 may affect the current supplied to a first LED load 130 regardless of what temperature is measured by an associated first temperature sensor 131), or is affected in aggregate by multiple temperature sensors 131 (e.g., an average temperature value of the first LED load 130 and the second LED load 130, as measured by a first temperature sensor 131 and a second temperature sensor 131 respectively, is used to affect the current provided to both LED loads 130). Additionally, when there are multiple LED loads 130, the power supplied to a given LED load 130 may be separately regulated (e.g., the power supplied to first LED load 130 may be different than the power supplied to second LED load 130) or commonly regulated (e.g., the power supplied to first LED load 130 is equal to the power supplied to second LED load 130 when power is supplied to both of the LED loads 130).
At DECISION 250, it is determined whether the operational current is below the nominal current. When the operational current is not below the nominal current, method 200 returns to OPERATION 220 to continue monitoring the heat of the LED load 130 with the present operational current being equal to the nominal current. When the operational current is below the nominal current, method 200 proceeds to OPERATION 260.
In various aspects where the operational current is adjusted in steps, the current controller 121 may set a time threshold between the determination in DECISION 230 and the determination in DECISION 250 so that a temperature fluctuating above and below the temperature threshold does not cause the current controller 121 to introduce flicker into the LED luminaire 100 as the operational current is adjusted upward and downward. A time threshold may be set via a number of clock cycles in a microprocessor between performing the operations, via an averaging of temperatures in a register, or the speed of the components in the current controller 121 (e.g., switching delays).
At OPERATION 260, the operational current is raised. As will be appreciated, the operational current may be raised in steps (e.g., 0% to 25% to 50% to 75% to 100%) or in a continuum similarly to how the operational current is reduced in OPERATION 240, but will not be raised to exceed the nominal current. Method 200 then returns to OPERATION 220 to continue monitoring the heat of the LED load 130.
Method 200 may conclude when the power source is removed, and may start again when the power source is reapplied.
Systems, devices or methods disclosed herein may include one or more of the features structures, methods, or combination thereof described herein. For example, a device or method may be implemented to include one or more of the features and/or processes above. It is intended that such device or method need not include all of the features and/or processes described herein, but may be implemented to include selected features and/or processes that provide useful structures and/or functionality.
Various modifications and additions can be made to the disclosed embodiments discussed above. Accordingly, the scope of the present disclosure should not be limited by the particular embodiments described above, but should be defined only by the claims set forth below and equivalents thereof.
The present disclosure claims benefit from U.S. Provisional Patent Application No. 62/348,389 filed on Jun. 10, 2016, the disclosure of which is incorporated herein in its entirety.
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