The present invention relates to field of LED lights, more specifically the field of controlling LED lights in conjunction with constant current drivers.
Constant current drivers are known to be useful in powering LED lights. A typical constant current driver can receive a range of input voltages while providing a constant output current. In other words, changing the input voltage used to power the constant current driver does not impact on the light output of a string of LED chips so long as the input voltage exceeds the minimum forward voltage (Vf) required to activate the LED string. Consequentially, LED are often used with a driver (typically the driver is what is known as a buck driver if the input voltage exceeds the voltage needed to drive the LEDs at the desired current) that is configured to provide a constant output current so long as the input voltage is within a range of input voltages that exceeds the forward voltage (Vf). For example, in an embodiment the constant current driver can receive an input of between Vf+2 to Vf+15 volts and provides a constant current output with a voltage that exceeds the Vf of the LED string. Many of these constant current drivers also have a dimming capability based on receipt of a signal, which can be an input V that ranges from 1X-10X (where X is the size of the voltage step between different signal levels) that can allow the amount of current to be reduced from 100 percent to 10 percent in 10 percent increments. While it is simple to provide the dimming voltage signal in many fixtures, certain individuals would appreciate an improved method of providing an input signal to fixtures suitable for use in track lighting applications or other applications where providing the input signal is not as easy.
A LED system includes an LED string of on ore more LEDs powered by a constant current driver. A voltage module is used to provide a first voltage (V1) that is greater than a forward voltage (VF) of the LED string and the first voltage is provided to power the constant current driver. A conversion circuit converts the first voltage V1 to a second voltage (VS) that is, at least in part, based on a percentage of the first voltage. The conversion circuit can include a voltage subtraction circuit to step down the first voltage before converting it to a percentage of the first voltage V1.
In an embodiment, the system can be a fixture that includes a first contact and a second contact that are powered by a voltage module, the voltage module configured to provide a first voltage to the first contact. The contacts can optionally be shaped as a rail. An LED module is mounted on the first and second contacts and includes a constant current driver. The constant current driver is configured to provide a current to an LED string supported by the LED module. The constant current driver includes an input signal and the constant current driver is configured to cause the output current to be reduced based on the voltage provided to the input signal. A conversion circuit is provided to convert the first voltage to a signal voltage and provide the signal voltage to the input signal. In an embodiment, the conversion causes the signal voltage to be a percentage of the first voltage so that the two voltages are proportionally related. The signal voltage can vary over the voltage range compatible with the input signal of the constant current driver. In another embodiment, the voltage step-down circuit is configured to provide a signal voltage that can range from about 10X to about 1X in response to the first voltage varying between so predetermined Vmax and VF by including a voltage subtraction circuit.
The present invention is illustrated by way of example and not limited in the accompanying figures in which like reference numerals indicate similar elements and in which:
The detailed description that follows describes exemplary embodiments and is not intended to be limited to the expressly disclosed combination(s). Therefore, unless otherwise noted, features disclosed herein may be combined together to form additional combinations that were not otherwise shown for purposes of brevity.
It should be noted that while the contacts 18, 20 are shaped in an elongated manner so as to prove a shape compatible with a rail configuration, in alternative embodiments the two contacts could be some other shape. Thus, the shape of the contacts is not intended to be limiting unless otherwise noted. It has been determined, however, that many of the benefits of the system disclosed herein is helpful in rail shaped systems; in part because providing a convention three-wire control system is somewhat awkward and less desirable.
An LED module 40 is mounted on the fixture 15 and includes a housing 41 with an LED emission area 42. The LED emission area includes a plurality of LEDs that are arranged in series. In certain embodiments there will be a number of LED series arranged in parallel. In other embodiments there will be a single string of LEDs. As can be appreciated, the LEDs can be simple chips mounted in desired manner (e.g., using a chip-on-board or COB package) or emitters that each include one or more LED chips. And, as is known, a phosphorous-based (or nano-dot based) disk can be provided to convert light emitted from the LED chips into a more desirable wavelength of light. For ease of discussion, however, the LED emission area will be considered string of one or more LEDs and the other features will not be further discussed.
A LED module 400, which is preferably removably mounted to the fixture, is schematically represented in
In order to provide a variable signal to the constant current driver, V1 is converted by the conversion circuit 440. If the voltage supply circuit 420 has limited functionality (or is omitted) then V1 can be adjusted remotely. If the voltage supply circuit 420 is capable be outputting different values for V1 then the voltage supply circuit 420 can be controlled directly. In an embodiment the direct control can be accomplished by providing a wireless signal that controls V1. Alternatively the voltage supply circuit 420 can include a manual switch or receive a control signal in a convention manner (e.g., be responsive to convention dimming controls).
Regardless of how it is provided, the voltage input V1 can varied over a range of voltages that all exceed the forward voltage VF of the LED string powered by the LED module 400 (e.g., V1 is varied within a normal operating range of the constant current driver 430). With a convention system, the change in voltage V1 would not impact the output of the constant current driver 430 as it would continue to output a constant current. Or, to put in another way, the change in voltage V1 would not cause the current being applied to the LED string 450 to change.
In order to use changes in V1 to provide dimming capabilities, a conversion circuit takes V1 and converts it to a range that corresponds to a desired input signal Vs for the corresponding constant current driver. For example, if V1 ranges between 24 and 12 volts, a resistive voltage divider based on the formula Vs=(Z2/(Z1+Z2)*V1 can be used to provide a signal that ranges from 1.0 to 0.5 volts by setting Z2=1 kΩ and Z1=23 kΩ. Naturally, the voltage divider can be adjusted so as to provide different conversion ratios/percentages if desired.
To provide for something closer to a 1.0-0.0 volt range signal, an op amp or any other suitable circuitry/component can be used to subtract some number of volts before using a voltage divider. In an example where the V1 varies from 24V to 12 V, 10 volts could be first subtracted and then the 14V to 2V range could be converted with a divider circuit having a setting of Z2=1 kΩ and Z1=10 kΩ. Naturally, the type of circuitry used can vary and there are a number of alternative circuits. Thus, the conversion circuit can be any desirable circuitry that takes an input voltage range and converts it to a predefined signal input range, where the input voltage range is greater than VF. One significant advantage of using a resistive voltage divider, however, is that resistive voltage dividers are relatively immune to changes in temperature because the coefficients tend to cancel out. It should be noted that in general, the values of resistance can expect to cause the voltage to be reduced by at least 4 times and in the above example, slightly more than 10 times.
As an example, but without limitation, if Vmax is 24 volts and Vmin is 15 volts, then the conversion circuit 540 could simply subtract 14 volts from the V1 and provide that as the input signal to the constant current driver 530. Thus, if the V1 was 15 volts then the input signal would be 1 volt and the current level would be set at 1/10 of the maximum current. Naturally, the conversion circuit 540 could also provide more complex conversions based on what Vmax and Vmin for the system and the desired input signal levels are for the constant current driver. While some drivers can provide 10 levels of current based on the corresponding signal input, some greater or lesser number of levels of current could also be provided. For example, the constant current driver could be configured to provide four levels of output based on four levels of input signal (and the levels of the input signal could be a range of voltages). Thus, considerable flexibility is possible.
It should be noted that while the embodiment depicted in
It should be noted that the conversion circuitry could be integrated directly into the constant current driver. One disadvantage of such integration is that it might require a custom constant current driver for each application and the cost to make a new driver is not insubstantial. However, it is contemplated that for higher volume applications it may make sense for the conversion circuit to be integrated and such integration is within the scope of the disclosure so long as the conversion circuit converts a range of voltages above VF to a corresponding signal level. Thus, for example and without limitation, the constant current driver 530 and conversion circuit 540, which are depicted separately, could also be provided as single element that is a constant current driver with an integrated conversion circuit.
The disclosure provided herein describes features in terms of preferred and exemplary embodiments thereof Numerous other embodiments, modifications and variations within the scope and spirit of the appended claims will occur to persons of ordinary skill in the art from a review of this disclosure.
This application claims priority to U.S. Provisional Application No. 61/759,847, filed Feb. 1, 2013, which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US14/14374 | 2/3/2014 | WO | 00 |
Number | Date | Country | |
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61759847 | Feb 2013 | US |