JP4222980B2 - LCD projector - Google Patents

Description

  The present invention relates to a liquid crystal projector.

  High-pressure mercury lamps (projection lamps) used in recent liquid crystal projectors are becoming ultra-high-pressure specifications as the brightness increases. For this reason, the arc jump position changes due to the arc jump due to the arc concentration of the electrode or the disturbance of the mercury air flow in the lamp due to the temperature drop on the electrode surface, and the probability of occurrence of flicker increases.

  Therefore, in order to reduce the occurrence probability of flicker, a pulse is always superimposed on the lamp current in the lamp ballast to prevent arc movement and stabilize the electrode temperature.

  Conventionally, a pulse is always superimposed on the lamp driving current regardless of the occurrence of flicker. As described above, if the pulse is constantly superimposed on the lamp driving current, the wear of the lamp electrode is promoted, and the lamp life may be shortened. Also, depending on the level of the superimposed pulse, the pulse noise may affect the signal system and appear as screen noise.

  An object of the present invention is to provide a liquid crystal projector capable of superimposing a pulse on a lamp current only when flicker occurs, extending the lamp life, and reducing the influence of pulse noise on a signal system.

  According to a first aspect of the present invention, in a liquid crystal projector provided with a pulse superimposing circuit for superimposing a pulse on a driving current of a projection lamp, a voltage between lamp electrodes of the projection lamp (hereinafter referred to as a lamp voltage) is predetermined. The absolute value ΔV of the difference between the detection means that detects every short period of time and the lamp voltage that is detected this time and the lamp voltage that is detected this time and the lamp voltage that is acquired last time is calculated, and ΔV is continuously greater than the predetermined value In this case, it is determined that flicker has occurred, and a control unit that superimposes a pulse on the driving current of the projection lamp for a certain period by a pulse superimposing circuit is provided.

  According to the present invention, it is possible to superimpose a pulse on the lamp current only when flicker occurs, thereby extending the lamp life and reducing the influence of pulse noise on the signal system.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 mainly shows a configuration of a lamp ballast unit provided in a liquid crystal projector.

  The AC plug is connected to the power supply circuit 1. The power supply circuit 1 supplies power to the main CPU 4 and the lamp ballast unit 2 of the liquid crystal projector. The lamp ballast unit 2 is connected to the projection lamp 3. The lamp ballast unit 2 is also connected to the main CPU 4 of the liquid crystal projector. The main CPU 4 controls the power supply circuit 1 and the lamp ballast unit 2.

  The lamp ballast unit 2 includes a power control circuit 11, a DC / AC conversion circuit 12, a high voltage generation circuit 13, a lamp voltage detection circuit 14, a pulse superposition circuit 15, and a sub CPU 16. The sub CPU 16 is connected to the main CPU 4.

  The DC power generated by the power supply circuit 1 is sent to the DC / AC conversion circuit 12 via the power control circuit 11. The DC / AC conversion circuit 12 converts direct current power into alternating current power. The AC power (lamp driving current) generated by the DC / AC conversion circuit 12 is supplied to the projection lamp 3 via the high voltage generation circuit 13. The high voltage generation circuit 13 generates high voltage power and supplies it to the projection lamp 3 at the start of lighting of the projection lamp 3. After the projection lamp 3 is lit, the AC power (lamp driving current) generated by the DC / AC conversion circuit 12 is supplied to the projection lamp 3 through the high-voltage generation circuit 13. The lamp voltage detection circuit 14 detects a voltage (lamp voltage) between the lamp electrodes when the lamp is lit. The sub CPU 16 controls each part in the lamp ballast unit 2 and communicates with the main CPU 4. The lamp voltage detected by the lamp voltage detection circuit 14 is sent to the main CPU 4 via the sub CPU 16.

  The main CPU 4 determines whether or not there has been a lamp voltage fluctuation of a predetermined voltage (for example, 0.5 V) or more within a predetermined time of 1 sec or less. If there is, it is determined that the flicker has occurred, and the pulse is superimposed on the output current of the DC / AC conversion circuit 12 for a certain period by the pulse superimposing circuit 15 via the sub CPU 16.

  2A shows the current waveform output from the DC / AC conversion circuit 12, that is, the waveform of the lamp driving current in a normal state, and FIG. 2B shows the output current of the DC / AC conversion circuit 12 (lamp driving). The current waveform when a pulse is superimposed on (current) is shown.

  FIG. 3 shows a pulse superimposition control processing procedure by the main CPU 4.

  First, when the lamp is turned on (step S1), it is determined whether or not a predetermined time T1 necessary for the lamp driving current to stabilize has elapsed (step S2). The predetermined time T1 is set to 2 minutes, for example.

When the predetermined time T1 has elapsed after lamp ignition takes the lamp voltage V _n is started (step S3). The ramp voltage V _n is taken every 100 ms.

When the lamp voltage V _n is fetched, the absolute value ΔV of the difference between the lamp voltage V _n fetched this time and the lamp voltage V _n−1 fetched last time is calculated (step S4). And it is discriminate | determined whether (DELTA) V is larger than predetermined value Vth (step S5). The predetermined value Vth is set to 0.5 [V], for example. When ΔV is less than or equal to the predetermined value Vth, the counter K is reset (K = 0) (step S6), and the process returns to step S3.

  In step S5, when ΔV is larger than the predetermined value Vth, the counter K is counted up (K = K + 1) (step S7), and then it is determined whether or not the count value K is larger than the predetermined value Ko (step S8). . The predetermined value Ko is set to 5 times, for example. If the count value K is less than or equal to the predetermined value Ko, the process returns to step S3.

  When it is determined in step S8 that the count value K is larger than the predetermined value Ko, that is, when ΔV exceeds the predetermined value Vth continuously (Ko + 1) times, it is determined that flicker has occurred. After resetting the counter K (K = 0) (step S9), a control signal (pulse ON signal) for driving the pulse superimposing circuit 15 is output (step S10). Thereby, since a pulse is output from the pulse superimposing circuit 15, the pulse is superimposed on the output current of the DC / AC conversion circuit 12. Thereafter, it waits for a predetermined time T2 to elapse (step S11). The predetermined time T2 is set to 60 sec, for example.

  When the predetermined time T2 has elapsed, a control signal (pulse OFF signal) for stopping driving of the pulse superimposing circuit 15 is output (step S12). Thereby, the driving of the pulse superimposing circuit 15 is stopped, and the pulse is not superimposed on the output current of the DC / AC conversion circuit 12. Thereafter, the process returns to step S3. The pulse superimposition control process ends when the lamp turn-off command is input.

  In the above embodiment, the case where the lamp driving current is AC has been described. However, the present invention can also be applied to the case where the lamp driving current is DC.

It is a block diagram which shows the structure of the lamp ballast unit mainly provided in the liquid crystal projector. 3 is a waveform diagram showing a current output from the DC / AC conversion circuit 12, that is, a lamp current in a normal state, and a lamp current when a pulse is superimposed on the output current of the DC / AC conversion circuit 12. FIG. It is a flowchart which shows the pulse superimposition control processing procedure by main CPU4.

Explanation of symbols

1 Power supply circuit 2 Lamp ballast unit 3 Projection lamp 4 Main CPU
11 Power control circuit 12 DC / AC conversion circuit 13 High voltage generation circuit 14 Lamp voltage detection circuit 15 Pulse superposition circuit 16 Sub CPU

Claims (1)

Detecting means for detecting a voltage between lamp electrodes of a projection lamp (hereinafter referred to as a lamp voltage) every predetermined short time in a liquid crystal projector having a pulse superimposing circuit for superimposing a pulse on a driving current of the projection lamp Then, the absolute value ΔV of the difference between the lamp voltage acquired this time detected by the detecting means and the lamp voltage acquired last time is calculated, and flicker occurs when ΔV continuously exceeds a predetermined value a predetermined number of times. And a control means for superimposing a pulse on the driving current of the projection lamp for a certain period by a pulse superimposing circuit.

Images