JP2005128402A - Liquid crystal projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal projector in which occurrence such as an explosion of a projection lamp caused by its service life is prevented regardless of dispersion that exists in the characteristics of the projection lamps. <P>SOLUTION: The liquid crystal projector is provided with a first means in which the voltage between the electrodes of a projection lamp (hereafter called initial lamp voltage) is detected based on a prescribed input operation while the lamp is turned on when the liquid crystal projector is installed and/or the projection lamp is exchanged and the initial lamp voltage is stored in a memory and a second means in which the voltage between the lamp electrodes (hereafter called lamp voltage) of the projection lamp is detected during a normal operation, the lamp voltage and the initial lamp voltage are compared to obtain a difference and the lamp is turned off when the difference exceeds a prescribed value. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a liquid crystal projector.

  In high-pressure mercury lamps (projection lamps) used in liquid crystal projectors, the voltage between lamp electrodes during lamp lighting (hereinafter referred to as lamp voltage) tends to increase with the lighting time. The lamp may rupture due to electrode breakage due to electrode wear.

  In order to prevent the lamp from exploding at the end of the lamp life, the lamp voltage is compared with a predetermined threshold (life determination threshold), and when the lamp voltage exceeds the threshold, the lamp lighting is stopped. Technology has already been developed. Conventionally, the lifetime determination threshold is fixed.

  By the way, the initial lamp voltage varies by about 40 V depending on the projection lamp. For this reason, if the lifetime determination threshold value is fixed as in the prior art, lighting of the projection lamp cannot be stopped before it is destroyed depending on the projection lamp.

For example, if the initial lamp voltage is high, the time until the lamp voltage reaches the lifetime judgment threshold is shortened, so that the lamp lighting is stopped even though there is no risk of the lamp bursting. End up. On the other hand, when the initial lamp voltage is low, the time until the lamp voltage reaches the threshold for determining the life becomes long, so that the lamp lighting is not stopped despite the risk of the lamp bursting. .
Japanese Patent Laid-Open No. 11-6980

  It is an object of the present invention to provide a liquid crystal projector that can prevent the projection lamp from bursting due to its lifetime regardless of variations in the characteristics of the projection lamp.

  According to the first aspect of the present invention, when the liquid crystal projector is installed and when the projection lamp is replaced, the voltage between the electrodes of the projection lamp during the lamp lighting state (hereinafter referred to as the lamp) is changed based on a predetermined input operation. A first means for detecting the initial lamp voltage) and storing it in the storage device, and during normal operation, the voltage between the lamp electrodes of the projection lamp when the lamp is lit (hereinafter referred to as the lamp voltage) is detected. A second means for comparing the lamp voltage with the initial lamp voltage and stopping the lamp lighting when the difference exceeds a predetermined value is provided.

  The invention according to claim 2 is provided with third means for notifying that the projection lamp should be replaced when the lamp lighting is stopped by the second means in the invention according to claim 1. It is characterized by.

  According to the present invention, it is possible to prevent the projection lamp from rupturing due to its life, regardless of variations in the characteristics of the projection lamp.

  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, and a sub CPU 15. The sub CPU 15 is connected to the main CPU 4. The main CPU 4 includes a storage device 5 for storing the initial lamp voltage Vs of the projection lamp 3 as will be described later.

  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 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, AC power 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 the voltage between the lamp electrodes when the lamp is lit. The sub CPU 15 controls each part in the lamp ballast unit 2 and communicates with the main CPU 4.

  When the liquid crystal projector is installed and when the projection lamp 3 is replaced, the main CPU 4 determines that the lamp is in the lamp lighting state detected by the lamp voltage detection circuit 14 based on a predetermined operation by the operator. The voltage (initial lamp voltage) Vs between the lamp electrodes at the time of normal lighting after the start is received via the sub CPU 15 and stored in the storage device 5.

  In the configuration as described above, when the projection lamp 3 is turned on, the lamp voltage detection circuit 14 detects the voltage between the lamp electrodes (lamp voltage) when the lamp is lit. The lamp voltage detected by the lamp voltage detection circuit 14 is sent to the main CPU 4 via the sub CPU 15. The main CPU 4 constantly monitors the lamp voltage Vx detected by the lamp voltage detection circuit 14 in the lamp lighting state (normal lighting after starting lighting).

  Then, the main CPU 4 calculates a difference ΔV (= Vx−Vs) between the lamp voltage Vx acquired from the lamp voltage detection circuit 14 via the sub CPU 15 and the initial lamp voltage Vs stored in the storage device 5. It is determined whether or not the difference ΔV exceeds a predetermined threshold value α. When it is determined that the difference ΔV exceeds the threshold value α, the main CPU 4 outputs an operation stop signal to the sub CPU 15 in the lamp ballast unit 2 and replaces the lamp with a lamp replacement indicator (light emitting diode or the like) of the liquid crystal projector. Tell the user what to do.

  When the sub CPU 15 in the lamp ballast unit 2 receives the operation stop signal from the main CPU 4, the sub CPU 15 stops the operation of each part in the lamp ballast unit 2 and stops the lamp lighting.

  In this embodiment, it is determined whether or not the lamp lighting should be stopped by determining whether or not the difference between the lamp voltage Vx of the projection lamp 3 and the initial lamp voltage Vs of the lamp exceeds a predetermined value α. Therefore, even if the initial lamp voltage of the projection lamp used varies, it is possible to prevent the projection lamp from exploding due to its life.

It is a block diagram which shows the structure of the lamp ballast unit mainly provided in the liquid crystal projector.

Explanation of symbols

1 Power supply circuit 2 Lamp ballast unit 3 Projection lamp 4 Main CPU
5 Storage Device 11 Power Control Circuit 12 DC / AC Conversion Circuit 13 High Voltage Generation Circuit 14 Lamp Voltage Detection Circuit 15 Sub CPU

Claims (2)

When the LCD projector is installed and when the projection lamp is replaced, the voltage between the electrodes of the projection lamp when the lamp is lit (hereinafter referred to as the initial lamp voltage) is detected based on a predetermined input operation. In the normal operation, the voltage between the lamp electrodes of the projection lamp (hereinafter referred to as the lamp voltage) is detected and the lamp voltage and the initial lamp voltage are calculated. A second means for comparing and stopping the lamp lighting when the difference exceeds a predetermined value;
A liquid crystal projector comprising: 2. The liquid crystal projector according to claim 1, further comprising third means for notifying that the projection lamp should be replaced when the lamp lighting is stopped by the second means.

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