Embodiments of the present disclosure relate to devices and methods of driving high efficiency ballasted lamps (i.e., white light emitting diodes (WLEDs) or cold cathode fluorescent lamps (CCFLs), and especially toward devices and methods for using high efficiency ballasted lamps with an electronic transformer.
Low voltage halogen lamps have been a popular replacement for incandescent lamps especially for decorative applications. They are more efficient than traditional incandescent lamps but not as efficient as the modern generation of lighting such as white light emitting diodes (WLEDs) or cold cathode fluorescent lamps (CCFLs). Halogen lamps run very hot and must be placed an appropriate distance away from any combustible materials. They also need a low voltage AC (or DC) supply (i.e., usually between 12 and 24 volts). Traditionally, a low voltage supply for halogen lamps was supplied from the AC source by a step-down transformer. These transformers, since they are designed for 50-60 Hz, must necessarily be made large and heavy. Although they are simple and reliable, they require a large amount of raw materials, especially copper and iron.
With reference to
The world's desperate need to conserve energy obligates the engineering community to look for low cost methods to retrofit halogen lights using e-transformers with high efficiency alternatives. For example, replacing the halogen lamp should be no more difficult than removing the old halogen bulb and replacing it with a bulb using suitable WLEDs. Due to the realization that halogen lamps are not particularly efficient there has been a trend to replace those halogen lamps with equivalently sized WLED lamps. A 50 W halogen lamp could ideally be replaced by a 10 W (or less) WLED lamp capable of producing the same amount of illumination. The potential power savings is enormous.
However, the problem with the WLED replacement strategy is that the electronic transformers that are used for halogen light fixtures require a minimum load larger than 10 Watts for proper operation. Since most WLED loads are smaller than 10 W these electronic transformers do not operate properly with WLED lamps. Compounding this problem is the situation that in some countries the e-transformer may be placed behind a wall or some locations that are not easily accessible by the consumer. Therefore, this problem will increase the cost of using high efficiency lighting beyond what many consumers would be willing to pay.
Therefore, there is a need for an approach to provide a device or means to allow an electronic transformer to be able to drive highly efficient lamps in a low power level condition, allowing the replacement of old halogen lamps from the existing fixtures with other high efficiency lamps.
These and other needs are addressed by the present disclosure, wherein an approach is provided for devices and methods for using high efficiency ballasted lamps with electronic transformers that are able to drive a lamp with a desired average output power lower than the minimum load requirement of the electronic transformer yet still make the electronic transformer operate properly.
Another approach is provided for devices and methods for using high efficiency ballasted lamps that are able to replace the old halogen lamps from the existing fixtures.
According to one aspect of an embodiment of the present disclosure, a method comprises acts of synchronizing a reference signal to a voltage corresponding to an AC voltage from an AC power source, and driving a load at a predetermined duty cycle operation.
The relation for the predetermined duty cycle can be defined as follows:
wherein
N×(the desired average output power)>the minimum load requirement of the electronic transformer, N is real positive number.
According to one aspect of an embodiment of the present disclosure, a device comprises a driver, a load, a bridge and a controller. The load is connected to the driver. The bridge has a rectifying bridge and a two rectifying diodes. The rectifying bridge is configured for providing a rectified power to the driver that drives the load. The two rectifying diodes are respectively connected to two output ends of an electronic transformer, and are configured for producing a resultant signal that is rectified from the output of the electronic transformer. The controller is connected between the two rectifying diodes and the driver, and receives the resultant signal to generate a control signal that enables the load through the driver for a duty cycle.
Accordingly, the present disclosure is able to provide a load made from a high efficiency ballasted lamp with a desired average output power lower than the minimum load requirement of the electronic transformer yet that still allows for proper operation of the electronic transformer.
The disclosure is illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings in which like reference numerals refer to similar elements and in which:
Embodiments of the apparatus and/or methods are disclosed. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the embodiments of the disclosure. It is apparent, however, to one skilled in the art that the present disclosure may be practiced without these specific details or with an equivalent arrangement.
With reference to
As shown in
The predetermined duty cycle is preset according to the relation of the minimum load requirement of the electronic transformer and the output power of the lamp (i.e. WLED). For example, imagine the minimum load requirement of the electronic transformer is 10 W and the output power of the WLED is 9 W. In general, the 9 W WLED does not provide enough of a load to maintain proper operation of the electronic transformer. In this example, the method in accordance with the present disclosure may make the electronic transformer drive the WLED at 18 W at a 50% duty cycle. The desired average output power will still only be 9 W yet when the WLED is on it provides an 18 W power load to the electronic transformer, which allows the electronic transformer with a minimum load requirement of 10 W to work properly. Therefore, instead of a continuous 9 W optical output, the present disclosure drives the WLED lamp at 18 W for 50% of the time.
Accordingly, the relation for the predetermined duty cycle can be defined as follows:
and
N×(the desired average output power)>the minimum load requirement, N is a positive real number.
In another example, suppose that the desired power output of the load is 3.5 W and the minimum load requirement of the electronic transformer is 15 W. Accordingly N is selected to be 5 in order to increase the operative power output of the e-transformer to 17.5 W, which is larger than the minimum load requirement of the electronic transformer. The operational duty cycle is 20%. Therefore, in this example, the lamp provides a 17.5 W load for the electronic transformer while maintaining an average 3.5 W output.
It is not necessary to increase the power dissipation capability of the WLED lamp even though they will be run at approximately 2 times (or more) the current that was originally intended. The limiting factor for many WLEDs is not current but rather the maximum heat that can be dissipated by the diodes. WLEDs are essentially point sources of light and heat, and thus they are notoriously bad at dissipating their own power, which is one of the major things that limits their lifetime, especially in poorly designed lamps. Since the WLEDs in use for the present disclosure are only on for a percentage of the time (e.g. 20% or 50%), the total power dissipation for the WLEDs is the same as in the continuous conduction where the driving current of the WLED is 20% and 50% as the examples described above.
In addition to the preceding issues, the ON and OFF frequency of the WLED lamp should be larger than 200 Hz in order to avoid deleterious health effects.
The frequency beating phenomenon means that the difference in output frequencies among different lamps may become noticeable to the lamp user, especially if the difference in frequency is small, on the order of several Hz. Although two different lamps are designed using the same structure or IC controller (i.e. using same frequency as an operating frequency), they will still has some difference in operating frequency due to process or operating variations. For example, if one lamp's frequency of operation is 200 Hz, and another s lamp runs at 203 Hz, then the difference in frequency would be 3 Hz. This difference would produce a visible flicker at 3 Hz (<120 Hz) which may make the lamp user feel uncomfortable. Many studies on this subject recommend a minimum lamp flicker frequency of 170 Hz or higher. The frequency beating phenomenon gets worse when a plurality of lamps is placed in a same viewing area. Accordingly, the step S10 that synchronizes a reference signal to a voltage corresponding to the AC voltage from the AC power source, allows all devices using this method of the present disclosure to use the same reference frequency, and thus the frequency beating phenomenon among lamps can be resolved. Step S10 can be implemented using a phase-locked loop (PLL) that synchronizes the operation of the invention to a frequency that corresponds to the AC voltage.
It would be ideal if the invention had direct access to the signal from AC power source in order to synchronize the lamp output to the AC voltage. Unfortunately, in most cases of WLED replacements for halogen lamps using the electronic transformers, direct access to the AC power source is prohibited and/or expensive. It is commercially desirable to use the output of the electronic transformer to synchronize lamp operation. However, the frequency of the output voltage from the electronic transformer is 20-40 kHz or higher, which is substantially different from the 50 or 60 Hz available from the AC mains.
With reference to
The controller 42 is connected between the cathodes of the two rectifying diodes 402 and the driver 44, and receives the resultant signal to generate a control signal that enables the load 46 through the driver 44 for the predetermined duty cycle (Step S20). In this embodiment, the controller 42 may comprise a phase-locked loop (PLL) unit 420 and a logical circuit 422 (e.g. a digital division). The PLL unit 420 synchronizes to time base reference signal 33, and the logical circuit provides higher synchronized frequencies in the PLL feedback loop. A person skilled in art is able to practice this without specific circuit arrangement details.
Once the PLL unit 420 has established a phase lock, the controller 42 then instructs the driver 44 to turn ON the load 46 at the appropriate time for a predetermined duty cycle (Step S20 shown in
The controller 42 may send out the control signal to enable the load 46 (through the driver 44) at a time (see signal 34 shown in
In the embodiment shown in
In
It is noted that synchronization is important to the present disclosure. Synchronization provides time information to the controller 42 to turn the load 460N and OFF at exact and specific times with relation to the incoming AC voltage. If the control signal of the controller 42 is not synchronized to the resultant signal, which corresponds to the AC voltage, the ON time of the load 46 might occur at wholly inappropriate times, such as when the AC voltage is near zero volts and the electronic transformer would have no opportunity to conduct.
A potential problem exists during startup in that in order to obtain the synchronized reference signal that the PLL needs to establish proper timing the electronic transformer needs to conduct, but without the proper enable signal to the WLED lamp, the electronic transformer will not operate properly, which will in turn not provide a synchronized reference signal before the phase lock. Some intervention is needed otherwise the electronic transformer 10 may never turn on properly.
As shown in
The dummy load 602 illustrated in the
Since there are many different variations of electronic transformer there may arise a situation where a particular electronic transformer will not start properly again after the load 46 has been turned off in the middle of a cycle. As further shown in
While the invention has been described in connection with a number of embodiments and implementations, the invention is not so limited but covers various obvious modifications and equivalent arrangements, which fall within the purview of the appended claims. Although features of the invention are expressed in certain combinations among the claims, it is contemplated that these features can be arranged in any combination and order.
This application claims priority benefit under 35 USC 119 of provisional patent application Ser. No. 61/526,253, filed 22 Aug. 2011.
Number | Date | Country | |
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61526253 | Aug 2011 | US |