Patent Grant
7298093
The invention relates to a cold cathode fluorescent lamp (CCFL) circuit and, more particularly, to devices for rapidly lighting a CCFL.
CCFL is a widely used light source in electronic devices such as scanners, LCD panels, notebook PCs and LCD televisions. Illumination of a conventional CCFL, however, may take up to 3 minutes to achieve stability after power up.
A method to drive a CCFL is provided by Johnson, et al. (U.S. Pat. No. 5,907,742, “Lamp control scheme for rapid warm-up of fluorescent lamp in office equipment”). The lamp is over-driven with high current for up to a predetermined time limit to accelerate mercury vaporization. The drive current is then reduced to a normal level. Between each use, the lower lamp current is 40% of the normal level to keep the lamp warm while extending the life of the product.
Using Johnson's Method, a certain amount of power is required when the CCFL is not working to maintain the temperature of the CCFL. The power consumed at the lower lamp current state is significant and additional logic circuits are required for controlling current in different states. Furthermore, if a longer length CCFL is utilized in electronic device 10, to raise the current when lighting the CCFLs, the CCFL circuit 12 receives higher voltage DC1 and generates higher voltage AC power. Consequently, transformers used in CCFL circuit 12 may not be capable of sustaining such a high voltage and may need to be upgraded, which leads to additional manufacturing cost.
A driving device for a CCFL circuit comprising at least one CCFL is provided. The driving device comprises: at least one heating device controlling the temperature of the CCFL; a power supply outputting a first voltage; a switching device having a first input terminal receiving the first voltage and a first and second output terminal outputting a second and third voltage respectively. The first output terminal is coupled to the CCFL circuit to output the second voltage when the first voltage is higher than a first level. The second output terminal is coupled to the heating device to output the third voltage when the first voltage is lower than the first level. The driving device further comprises a controller controlling the power supply to output the first voltage higher than the first level to light the CCFL, and lower than the first level to control the temperature of the CCFL.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the features, advantages, and principles of the invention.
The invention provides a heating device maintaining the temperature of an idle CCFL, and enabling rapid lighting thereof.
The electronic device 20 comprises a driving device 21 and a CCFL circuit 22 comprising at least one CCFL 221. Driving device 21 comprises a controller 211, a power supply 212, a switching device 213 and a heating device 214.
Power supply 212 outputs a first voltage DC1, controlled by the controller 211. Switching device 213 has a first input terminal receiving the first voltage DC1 and a first and second output terminal. The first output terminal is coupled to the CCFL circuit 22 outputting the second voltage DC2 when the first voltage DC1 is higher than a first level V1. The second output terminal is coupled to the heating device 214 outputting the third voltage DC3 when the first voltage DC1 is lower than the first level V1. In this embodiment, the controller 211 controls the power supply 212 to output the first DC voltage DC1 higher than the first level V1 to light the CCFL 221. The voltage switching device 213 provides the second DC voltage DC2 to the CCFL circuit 22 for lighting the CCFL 221. Simultaneously, the third DC voltage DC3 is cut off. Thus, the heating device stops working.
Additionally, controller 211 controls the power supply 212 to output the first DC voltage DC1 lower than the first level V1 to control the temperature of the CCFL 211 when the CCFL 211 is idle. The voltage switching device 213 cuts off the second DC voltage DC2 and the power supply 212 snuffs out the CCFL 221. Simultaneously, the third DC voltage DC3 is output. The heating device 214 heats the CCFL 221 such that the CCFL 221 is rapidly lit when required next time.
In this embodiment, a simply two-state DC voltage control method is utilized to control a boot mode and a sleep mode of the CCFL. In the sleep mode, the CCFL is idle and stops receiving current. In the sleep mode, the temperature of the CCFL is maintained such that the power consumption caused by the CCFL is solved.
A second level V2 higher than the first level V1 is provided for an extra function of this embodiment. The function of the first output terminal of switching device 23 remains the same. The second output terminal of switching device 23 outputs the third voltage DC3 when the first voltage DC1 is lower than the first level V1 or higher than the second level V2. In this embodiment, when the first voltage is higher than the second level V2, the CCFL is lit and the heating device 214 heats the CCFL 221. The temperature of the CCFL 221 may be increased rapidly and illumination of the CCFL 221 may rapidly reach the working illumination.
In this embodiment, controller 211 controls the power supply 21 to light the CCFL 221 when the first DC voltage DC1 is higher than the first level V1 and lower than the second level V2. The voltage switching device 213 provides the second DC voltage DC2 to the CCFL circuit 22 for lighting the CCFL 221. Simultaneously, the third DC voltage DC3 is cut off such that the heating device stops working.
Additionally, controller 221 controls the power supply 21 to output the first DC voltage DC1 lower than the first level V1 when the CCFL stops working. The voltage switching device 213 cuts off the second DC voltage DC2 such that the CCFL circuit 22 snuffs out the CCFL 221. Simultaneously, the third DC voltage DC3 is output such that the heating device 214 heats the CCFL 221. Thus, the CCFL 221 is lit rapidly when required next time.
Controller 211 further controls the power supply 21 to output the first DC voltage DC1 higher than the second level V2 to rapidly light the CCFL 221. The voltage switching device 213 provides the second DC voltage DC2 to the CCFL circuit 22 for lighting the CCFL 221. Simultaneously, the third DC voltage DC3 is output such that the heating device 214 heats the CCFL 221. Thus, the temperature of the CCFL 221 rapidly arrives an operation temperature.
In this embodiment, a simply three-state DC voltage control method is utilized to control a rapid light mode, a boot mode, and a sleep mode of the CCFL. In the rapid light mode, since the CCFL is heated, the CCFL is not required to receiving a higher current and the CCFL is rapidly lit. In the sleep mode, the CCFL is idle and the CCFL is not required to receive current. In the sleep mode. the temperature of the CCFL is maintained such that the power consumption caused by the CCFL is solved.
While the invention has been described by way of example and in terms of preferred embodiment, it is to be understood that the invention is not limited thereto. Those who are skilled in this technology can still make various alterations and modifications without departing from the scope and spirit of this invention. Therefore, the scope of the present invention shall be defined and protected by the following claims and their equivalents.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2005 1 0073970 | May 2005 | CN | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 5336976 | Webb et al. | Aug 1994 | A |
| 5907742 | Johnson et al. | May 1999 | A |
| 6198234 | Henry | Mar 2001 | B1 |
| 20060071601 | Yamada et al. | Apr 2006 | A1 |
| Number | Date | Country |
|---|---|---|
| 11-305196 | Nov 1999 | JP |
| I226788 | Jan 2005 | TW |
| Number | Date | Country | |
|---|---|---|---|
| 20060261750 A1 | Nov 2006 | US |
