The present application relates to control devices and methods for light fixtures, for example light emitting diode (LED) light fixtures.
LEDs are increasingly being adopted in a wide variety of lighting applications, for example, automobile head and tail lights, street lighting, architecture lighting, backlights for liquid crystal display devices, and flashlights, to name a few. LEDs have significant advantages over conventional lighting sources such as incandescent lamps and fluorescent lamps. Such advantages include high power efficiency, good directionality, color stability, high reliability, long life time, small size and environmental safety.
Some challenges related to thermal management and associated with most LEDs and their applications are identified and discussed. Some of these thermal challenges can be mitigated or resolved by using a thermal foldback control circuit that provides control signals to a dimmer control embedded in an LED driver. Next, the components, structure, functions, and implementations of various configurations of thermal foldback control circuits are described.
Although LEDs represent a relatively new market for illumination applications, LEDs as an alternative to conventional lighting products also brings with it certain demanding thermal challenges. That is, the efficiency of LEDs strongly depends on the junction temperature of the device. For example, the lumens (or light intensity) generated by an LED generally decreases in a linear manner as the junction temperature increases. The lifetime for the LED also decreases as the junction temperature increases.
Some lighting system manufacturers address these thermal challenges by designing systems with appropriate heat sinks, high thermal conductivity enclosures, and other thermal design techniques. These thermal design techniques, however, do not consider the LED driver integrated circuit (IC) as a control component in the thermal management system.
The LED driver can be used as a control component to modify the drive current of the LED based on temperature. As a result, the use of an LED driver with intelligent over-temperature protection provides an additional control mechanism that can increase the lifetime of LED light sources significantly, ensuring the rated lifetime and reducing the incidence of defective products.
Depending on the lighting manufacturer and application, the useful lifetime for LED lighting products ranges from approximately 20,000 hours to more than 50,000 hours, compared to less than 2,000 hours for incandescent bulbs. However, as the junction temperature increases not only does the light output of an LED decrease, but the lifetime of the LED decreases as well. Intelligent thermal protection can also help reduce system cost by enabling system integrators to design the heat sink with lower safety margin.
Typically, the design of a thermal management system for an LED lighting device is focused on the heat sink and printed circuit board (PCB) design, while the opportunities for thermal management by the LED driver IC and driving circuit are not considered. Intelligent over-temperature protection by the LED driver IC can increase the lifetime of LED light sources significantly.
Temperature protection with LED driver ICs has been implemented in a variety of ways. Some LED driver devices include a sense pin to which an external temperature sensor may be attached. Different temperature sensing devices, including diodes, on-chip sensors, positive temperature coefficient (PTC) or negative temperature coefficient (NTC) thermistors can be used in LED lighting applications to assist in protecting the LEDs from overheating. After the temperature is accurately sensed, the response to any over-temperature condition is then implemented. One response is to quickly turn-off the drive current to the LEDs when a threshold temperature is exceeded. Lighting devices that include this type of response then “restart” the light source when the temperature is reduced, or alternatively, wait until a power cycle occurs, which typically restarts the lamp. There are some disadvantages related to this method, however.
For example, the abrupt shut-down method often requires the threshold temperature to be set high, to avoid incorrectly triggering a shutdown of the lamp. While this high threshold may protect the lamp from a catastrophic failure it still can lead to significant reduction in the lifetime of the LEDs. Also, turning off the LED current means that the light is switched off abruptly. This can cause a serious situation like panic in public areas. Many known LED drivers automatically restart when the system has cooled, and once restarted the system heats up and shuts-down repeatedly, resulting in a disturbing “flicker” effect.
Embodiments of the application help solve the above-mentioned issue by, in one embodiment, providing a thermal foldback control circuit electrically connected to a light emitting diode (LED) driver. the thermal foldback control circuit includes a voltage divider and a shunt regulator. The voltage divider includes a first resistor component, a second resistor component in a series-type configuration with the first resistor component, and an output. The first resistor component has a first resistance and the second resistor component has a second resistance that varies in response to a temperature at a reference point. The output is configured to output a reference voltage based on the first resistance and the second resistance. The shunt regulator is in a parallel-type configuration with the voltage divider and is configured to receive the reference voltage and control a driver output of the LED driver based on the reference voltage.
In another embodiment, the application provides a light emitting diode (LED) system including one or more LEDs, an LED driver providing power to the one or more LEDs, and a thermal foldback control circuit. The thermal foldback control circuit is electrically connected to the LED driver and is configured to output a control signal to the driver based on a temperature at a reference point.
In another embodiment, the application provides a method of controlling power to one or more LEDs. The method includes sensing a temperature at a reference point; comparing the sensed temperature to a predetermined temperature threshold; and reducing power to the one or more LEDs when the sensed temperature passes the predetermined temperature threshold.
Other aspects of the application will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the application are explained in detail, it is to be understood that the application is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The application is capable of other embodiments and of being practiced or of being carried out in various ways.
It should be noted that the phrase “series-type configuration” as used herein refers to a circuit arrangement where the described elements are arranged, in general, in a sequential fashion such that the output of one element is coupled to the input of another, but the same current may not necessarily pass through each element. For example, in a “series-type configuration,” it is possible for additional circuit elements to be connected in parallel with one or more of the elements in the “series-type configuration.” Furthermore, additional circuit elements can be connected at nodes in the series-type configuration such that branches in the circuit are present. Therefore, elements in a series-type configuration do not necessarily form a true “series circuit.”
Additionally, the phrase “parallel-type configuration” as used herein refers to a circuit arrangement where the described elements are arranged, in general, in a manner such that one element is connected to another element, such that the circuit forms a parallel branch of the circuit arrangement. In such a configuration, the individual elements of the circuit may not necessarily have the same potential difference across them individually. For example, in a parallel-type configuration of the circuit it is possible for two circuit elements that are in parallel with one another to be connected in series with one or more additional elements of the circuit. Therefore, a circuit in a “parallel-type configuration” can include elements that do not necessarily individually form a true parallel circuit.
The LED driver 102 includes a dimmer interface 110 designed to connect to a standard dimmer switch (not shown) utilizing a positive and negative electrical connection 112. In one embodiment, the dimmer interface 110 drives a current and senses a voltage. The sensed voltage output of the dimmer interface 110 determines the current or the voltage generated by the LED driver to the LEDs. Typically, a dimmer switch includes some type of potentiometer to vary the resistance, which changes the voltage generated by the dimmer switch. In various embodiments, the dimmer interface 110 is a 0-10V dimmer interface, which senses a voltage between 0-10 volts (V). LED driver 102 has a 0-10V dimmer interface 110, such as a Dialog Semiconductor IW3630, which is commercially available and includes different components to perform various functions as would be understood by one of ordinary skill in the art.
The thermal foldback device 100 can use the dimmer interface 110 of the LED driver 102 for thermal management. The thermal foldback device 100 is connected to the LED driver 102 through the dimmer interface 110. The thermal foldback device 100 is designed to sense the temperature of a specific point based on the location of thermal foldback device 100, or specifically the thermistors (or resistors) of the thermal foldback device 100. If the sensed temperature exceeds a reference temperature, the thermal foldback device 100 automatically provides a signal to the LED driver 102 to dim the light source. The LED driver 102 dims the light modules by reducing the supplied current to the light source. The reduced light decreases the heat generated by the light sources thereby stopping any increase in temperature and acting to reduce the temperature. If the temperature continues to increase, the thermal foldback device 100 causes the LED driver 102 to dim the lights further and with appropriate driver may be configured to turn off the light sources completely. Once the temperature returns to a safe operating level, the thermal foldback device 100 signals the LED driver 102 to increase the current or voltage supplied to the light sources back to a normal illumination level. Through this process, the thermal foldback device 100 can be used to set an equilibrium level of LED illumination based on a predetermined maximum allowable temperature indicating overheating. By preventing overheating, the thermal foldback device 100 helps increase the life of the LED driver 102 and LED engine 104 and protect these and other components from premature failure.
In various embodiments, the thermal foldback device 100 is connected to or near a reference point to measure the temperature at a specific location. For example, the thermal foldback device 100 can be connected to the LED driver 102, the LED engine 104, LED, or other hot or temperature sensitive spots in the light fixture. The connection must be a thermal and mechanical connection. In various embodiments, the thermal foldback device 100 is connected to more than one reference point, or multiple thermal foldback devices 100 may be connected to different reference points. When multiple thermal foldback devices 100 are used, the thermal foldback devices 100 can be connected in parallel. The upper limit of the reference points monitored depends on the dimming driver source current rating, the size, and configuration of the associated light fixture as would be understood by one of ordinary skill in the art.
The first resistor component 122 may be a resistor or a thermistor, for example but not limited to, a negative temperature coefficient (NTC) type thermistor or a positive temperature coefficient (PTC) type thermistor. The second resistor component 124 may be a resistor or a thermistor, for example but not limited to, a negative temperature coefficient (NTC) type thermistor or a positive temperature coefficient (PTC) type thermistor. In one embodiment, at least one resistor component 122, 124 is a thermistor. If both resistor component 122, 124 are thermistors, the control circuit 120 of the thermal foldback device 100 may also provide dimming functions. In one embodiment, the control circuit utilizes a single thermistor, so that only one of the first and second resistor components 122, 124 is a thermistor and the other is a resistor.
The control circuit 120 also includes a shunt regulator 126. In some embodiments, the shunt regulator 126 is in a parallel-type configuration with the first and second resistor components 122, 124. In various embodiments, the shunt regulator 126 (or shunt voltage regulator) is a low-voltage adjustable precision shunt regulator (e.g., TLV431). In various embodiments, the shunt regulator 126 utilizes a Zener diode, an avalanche breakdown diode, or a voltage regulator tube. In some embodiments, the shunt regulator 126 is a three terminal device with an anode, cathode, and reference voltage terminal. The anode of the shunt regulator 126 is electrically connected to a first terminal of the second resistor component 124 and to a negative terminal 128 of the control circuit 120 (or dimming interface 110). The cathode of the shunt regulator 126 is electrically connected to a first terminal of the first resistor component 122 and to a positive terminal 129 of the control circuit 120 (or dimming interface 110). The reference input voltage terminal of the shunt regulator 126 is electrically connected between the first and second resistor components 122, 124 (i.e., a second terminal of the first resistor component 122 and a second terminal of the second resistor component 124). The shunt regulator 126 has a specified thermal stability over applicable industrial and commercial temperature ranges. In the embodiment, the control circuit 120 is powered from a current source. The current source can be provided from the current supplied to a light source or a secondary output current from the LED driver 102, such as the 0-10V dimmer interface 110.
The first resistor component 122 and second resistor component 124 provide a variable voltage divider for the reference voltage of the shunt regulator 126, so the reference voltage varies based on temperature. In a PTC embodiment, the first resistor component 122 is a resistor and the second resistor 124 component is a PTC thermistor. As the temperature increases, the PTC thermistor will increase its resistance at a faster rate than the resistor, which will increase the voltage to the reference input terminal causing the reference output voltage to fall and the current to sink. Because the PTC can be a device with linear change in resistance relative to temperature, the change in voltage is also substantially linear. As the reference input terminal increases, a threshold voltage, (the rated value of the reference device) is crossed and the shunt regulator 126 begins diverting (or sinking) a portion of drive current from the current source (e.g., from the dimming interface 110) away from the voltage divider, thus lowering the voltage across the positive terminal 129 and the negative terminal 128 of the control circuit 120. The lower voltage at the dimming interface lowers the current and voltage output of the LED driver 102 as dictated by the relationship between voltage and current through a diode, which dims the LED. The dimmed LED generates less heat and lowers the temperature sensed by the control circuit 120.
In a NTC embodiment, the first resistor component 122 is a NTC thermistor and the second resistor 124 component is a resistor. As the temperature increases, the NTC thermistor will decrease its resistance at a faster rate than the resistor, which will increase the input voltage to the reference terminal causing the reference output voltage to fall as it sinks current, similar to the PTC embodiment. Because the NTC can be a device with linear change in resistance relative to temperature, the change in voltage is also substantially linear. As the reference input terminal increases, a threshold voltage is crossed and the shunt regulator 126 begins diverting (or sinking) a portion of drive current from the current source (e.g., from the dimming interface 110) away from the voltage divider, which lowers the voltage across the positive terminal 129 and the negative terminal 128 of the control circuit 120. The lower voltage at the dimming interface lowers the current and voltage output of the LED driver 102 as dictated by the relationship between voltage and current through a diode, which dims the LED. Either the PTC or NTC embodiment lowers the reference output voltage, (sinks more current) as the temperature increases and increases the reference output voltage, (sinks less current) as the temperature decreases. When the sensed temperature causes the voltage divider to increases above the threshold voltage, (the rated value of the reference device), the current through the shunt regulator 126 is turned on.
Thus, the first and second resistor components 122, 124 and the shunt regulator 126 are configured so that as the sensed temperature increases, the resistance of the thermistor changes (e.g., increases with a PTC or decreases with a NTC), which changes the reference voltage input of the shunt regulator 126. When the reference input voltage reaches a certain threshold level, (the rated value of the reference device) the shunt regulator 126 sinks current and lowers the voltage across the positive terminal 129 and the negative terminal 128 of the control circuit 120. The lower voltage causes the LED driver 102 to reduce the light output of the LED engine 104. The threshold level is chosen close the minimum dimming voltage of a 0 to 10V system, typically about 1V to allow normal operation and provide dimming control when the heat is excessive. Additional components may be used in addition to or in place of those described to create a temperature sensitive circuit that provides a control signal to a driver to dim or otherwise reduce the light output of a light fixture as would be understood by one of ordinary skill in the art when viewing this disclosure. For example, a potentiometer may be provide to allow a user to adjust maximum light output of a light fixture or components to allow a user to adjust the maximum light output of the light fixture via the thermal foldback device 100.
According to one embodiment, thermal foldback device 100 (
In certain embodiments, the thermal foldback device 100 integrates more than one temperature sensitive unit mounted at different reference points. More than one thermal foldback device 100 may also be positioned at different reference points and connected to the driver 102. The upper limit of thermal foldback devices 100 and/or monitored reference points depends on the size and configuration of the associated light fixture as would be understood by one of ordinary skill in the art.
The temperature may be monitored at a plurality of references points and the current supplied to the light emitters reduced when the temperature at any of the reference points crosses a predetermined threshold value. The threshold values at each reference point need not be identical, and each threshold value may be designed to meet a requirement of a particular point of interest. For example, the temperature threshold for an LED driver 102 may be different from the temperature threshold for an LED engine 104.
In one embodiment, the thermal foldback device 100 is physically connected to a component of the light fixture, for example a driver case 146 and operatively connected to the light emitting devices through the LED driver 102, for example through a dimmer interface 110. In various embodiments, the thermal foldback device 100 is configured to operate with any 0-10V control. If the temperature threshold value, for example approximately 80° C., is exceeded, the thermal foldback device 100 causes the driver 102 to dim the light emitting devices, for example by reducing the supplied current, to reduce the brightness and heat output of the light emitting devices. If the temperature continues to rise, the current supplied to the light emitting devices is reduced further. The reduction in current may have a linear relation with the rise in temperature, or a curved or stepped relationship as desired. A second threshold value may also be established that turns off the light emitting devices completely.
Thus, the application provides, among other things, a {text}. Various features and advantages of the application are set forth in the following claims.
This application claims the benefit to U.S. Provisional Application No. 62/118,746, filed on Feb. 20, 2015, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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62118746 | Feb 2015 | US |