JPH0460534A - Air flow system of liquid crystal projector - Google Patents

Abstract

PURPOSE:To perform control so that the projector can operate and to monitor the cause of abnormality by controlling the air speed of each liquid crystal panel with data detected by a temperature detecting means and an air speed detecting means. CONSTITUTION:Air speed sensors 14 are installed by liquid crystal panels 10R, 10G, and 10B of the primary colors R, G, and B and detect air speeds at their positions to send them out to an air speed comparing means 18 of a microcomputer 17 as a control means. When the air speed which is detected is 0 owing to the stop of a cooling fan 13, a power source 19 is turned off so as to protect the liquid panels 10. Further, when the air speed is less than a filter clogging set air speed (v) set on the side of the microcomputer 17 although lamp energy W and ambient temperature T vary, the comparing means 18 judges clogging and turns on a clogging monitor 20 to let a user know that to take counter measure. Consequently, the rotating speeds of the cooling fan 13 and an air discharging fan can be controlled corresponding to the ambient temperature and the clogging of a filter can be monitored.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an air flow system for a liquid crystal projector that controls wind speed in order to suppress a rise in temperature of a liquid crystal panel in response to a rise in ambient temperature [Prior art] For example, as shown in FIG. 4, the liquid crystal projector P' includes a light source 2 with a reflector 1, a cold mirror 3, a dichroic mirror 4.5 for color separation, and a reflection mirror 6.5 for changing the optical path. 7 and.

Dichroic mirror 8.9 for color synthesis, three primary colors R,
It is composed of G, B liquid crystal panels IOR, IOC, 10B, and a projection lens 11.

The light emitted from the light source 2 and the reflector 1
The heat rays of the reflected light are removed by a cold mirror 3, and the dichroic mirror 4.5 for color separation removes the heat rays from the light.
It is separated into G and H.

The separated light of the three primary colors is displayed on the LCD panel l0R10G, I
After passing through the OB, the images are combined again, and a full-color image is projected onto the screen by the projection lens 11.

In such a liquid crystal projector-P', in order to obtain a high-brightness image, high-energy light passes through each liquid crystal panel IOR, LOG, IOB.Such high-energy light passes through each liquid crystal panel 10R, IOG, When passing through the IOB, the liquid crystal panels IOR, LOG,
As the temperature of the IOH increases, cooling is required to protect the liquid crystal.

As shown in FIG. 5, this cooling is achieved by sucking outside air with one cooling fan 13' installed on the side of each liquid crystal panel IOR.
, IOG, and IOB, the rising air was discharged by an exhaust fan 31.

Note that a filter 32 is installed in front of the above-mentioned cooling fan 13' to supply clean air.

Furthermore, the filter 32 may become clogged, the cooling fan 13',
A temperature sensor 15' is installed to detect the temperature rise and turn off the set power when the internal temperature rises due to a failure of the exhaust fan 31 or the like.

[Problems to be Solved by the Invention] In the liquid crystal projector P', when the internal temperature rises, detecting this with the temperature sensor 15' and turning off the set power is necessary for the liquid crystal panels IOR and LOG. ,
It is important to protect the IOB, but since the cause of the temperature rise is unknown, appropriate measures cannot be taken, and there is only one cooling fan for three LCD panels, so there is no air passage. A sufficient cooling effect could not be obtained.

This invention was made in view of the above points, and detects the wind speed of the cooling air and the ambient temperature, which determine the temperature of the liquid crystal panel, and predicts the temperature of the liquid crystal panel based on the detected values. An object of the present invention is to provide an air flow system for a liquid crystal projector that can control the liquid crystal projector so that it can operate within a range of conditions and can monitor the cause of abnormality.

[! ! Means for solving the problem] The above r! 1. In order to solve this problem, the present invention includes a temperature detection means for detecting the ambient temperature at each liquid crystal panel position, a wind speed detection means for detecting the ambient wind speed at each liquid crystal panel position, and a wind speed detection means for detecting the ambient wind speed at each liquid crystal panel position. The present invention is characterized in that the wind speed of each liquid crystal panel is controlled based on data detected from the air flow means, the temperature detection means, and the wind speed detection means.

[Function] In FIGS. 1 and 2 showing an embodiment of this invention,
When the lamp energy W emitted from the light s2 hits the liquid crystal panels 10R, 10G, 10B, the temperature of the liquid crystal panels IOR, IOG, 10B is Y'
In order to suppress the temperature to C, it is determined that the wind at T'C from the cooling fan 13 is required to be V m/s, so the rotational speed of the cooling fan 13 and the exhaust fan can be controlled according to the lamp energy and ambient temperature. .

Further, by detecting the wind speed, it is possible to monitor whether or not the filter 16 crosses over, and the power is turned off when the fan is stopped or when the ambient temperature rises.

[Embodiment] Next, an embodiment of the air flow system for a liquid crystal projector according to the present invention will be described in detail with reference to FIGS. 1 to 3.

FIG. 1 is a schematic configuration diagram showing an example of an implementation of an air flow system for a liquid crystal projector according to the present invention.

In FIG. 1, a liquid crystal projector P includes a light source 2 with a reflector 1, a cold mirror 3, a dichroic mirror 4.5 for color separation, a reflection mirror 6.7 for optical path conversion, and a color synthesis dichroic mirror for 8.9
and BJI color R, G B LCD panels IOR, IOG
, IOB, and a projection lens 11.

And 3 primary color R, G, B liquid crystal panel l0R10
Air passages 12 are formed on each front surface of G and 10B, and cooling fans 13 are installed on the sides thereof.

A wind speed sensor 14 and a temperature sensor 15 are installed at the outlet of each air passage 12 (see FIG. 2).

A reflector 1 of a liquid crystal projector P reflects light emitted from a light source 2 using a parabolic reflecting mirror and emits the reflected light.

As the light source 2, for example, a metal halide lamp containing a metal halide is used.

The cold mirror 3 reflects only visible light and transmits infrared and ultraviolet rays.

A dichroic mirror 4 for color separation separately reflects red light and transmits other light.

The dichroic mirror 5 separates and reflects the blue light and transmits only the remaining green light.

The reflection mirror 6.7 for changing the optical path is a total reflection mirror that reflects all the incident light.

The guichroic mirror 8.9 for color synthesis is the liquid crystal panel I.
Combines the light transmitted through ORIOG and IOB.

The projection lens 11 projects the combined image light onto a screen (not shown).

The cooling fan 13 is a panel cooling means, and a filter 16 (see FIG. 2) is installed on the intake side, and is controlled by a control means described later.

The wind speed sensor 14 is a wind speed detection means, and is a wind speed detection means for each liquid crystal panel IO.
Detects the wind speed on the incident side of RLOG and IOB.

The temperature sensor 15 is a temperature detection means, and is a temperature detection means for each liquid crystal panel IO.
Detects the temperature on the incident side of RIOG and IOB.

Figure 2 shows the liquid crystal panel, cooling fan, wind speed sensor,
It is a partially omitted plan cross-sectional view showing the positional relationship of temperature sensors.

In such a liquid crystal projector-P, three primary colors R,
The temperatures Y of the liquid crystal panels IQR, LOG, and 10B of G and B are determined by the wind speed V of the cooling air and the ambient temperature T.

Therefore, the liquid crystal panel 10. In order to keep the temperatures Y of R, LOG, and IOB below a certain value, it is determined how many degrees Celsius and how many m/s of wind are required depending on the ambient temperature T.

FIG. 3 is a block diagram showing an example of an air flow system for a liquid crystal projector according to the present invention.

In this FIG. 3, the wind speed sensor 14 has three primary colors R, G.
, B are installed on the sides of the liquid crystal panels IOR, IOG, 10B (see 20th reference), detect the wind speed at that position, and send it to the wind speed comparison means 18 in the microcomputer 17, which is the control means.

If the detected wind speed is “0” due to the cooling fan 13 stopping, etc.
”, the power supply 19 is turned off to protect the liquid crystal panel 10.
to rOFFJ (V=O).

In addition, if the lamp energy W and the ambient temperature T do not change, but the wind speed is less than the filter clogging set wind speed V set on the microcomputer 17 side, the comparison means 18 determines that the filter is clogged. The monitor 20 is turned on to notify the user and have him take action (0<V≦v).

If the detected wind speed V is equal to or higher than the filter clogging setting wind speed V, the data is sent to the system controller 21 of the microcomputer 17 (V>v).

The temperature sensor 15, like the wind speed sensor 14, is placed on the side of the liquid crystal panels IOR, LOG, and I0B (see Figure 2), and detects the temperature at that position as the ambient temperature T.
It is sent to comparison means 22 for temperature.

If the detected ambient temperature T is lower than the operating upper limit temperature t, the data is sent to the system controller 21 of the microcomputer 17 (Tit).

When the detected ambient temperature T is higher than the operating upper limit temperature t, the power supply 19 is set to FFJ (T≧t) to protect the liquid crystal panel 10.

The system controller 21 of the microcomputer 17, based on each data sent from the wind speed comparison means 18 and the temperature comparison means 22, if the comprehensively determined function is smaller than the panel guaranteed temperature y, Sends a command for continued use and returns to normal operation (Y<3/).

Note that if the overall judgment constant is greater than the guaranteed panel temperature y, the power supply 19 is turned off (Y≧y).

[Effects of the Invention] As described above, the air flow system for a liquid crystal projector according to the present invention cositrolls the temperature of each liquid crystal panel based on the data detected from the means for detecting the ambient temperature and wind speed at each liquid crystal panel position. This is a mechanism designed to do this.

In other words, in order to suppress the temperature of the liquid crystal panel to Y'C, it is determined that the air flow of T'C from the cooling fan is required to be V m /' S, so the rotation of the cooling fan and exhaust fan is adjusted according to the ambient temperature. You can control the number.

Additionally, by detecting the wind speed, it is possible to monitor filter clogging, and the power can be turned off when the fan is stopped or the ambient temperature rises.

0R LCD projector 10G, 10B LCD panel, air path cooling fan, wind speed sensor, microcomputer power supply, clogging monitor 4, brief description of screen I21 Figure 1 is an example of implementation of the air flow system of the liquid crystal projector according to the present invention. FIG. 2 is a partially omitted plan cross-sectional view, FIG. 3 is a functional block diagram showing an example of implementation of the air flow system of the liquid crystal projector according to the present invention, and FIG. 4 is a diagram of a conventional liquid crystal projector. 5 is a schematic plan cross-sectional view thereof.

fOR liquid crystal channel No. figure

Claims (1)

[Claims] (1) Temperature detection means for detecting the ambient temperature at each liquid crystal panel position; Wind speed detection means for detecting the ambient wind speed at each liquid crystal panel position; Air path means for cooling each liquid crystal panel; Temperature detection means; An air flow system for a liquid crystal projector characterized by controlling the wind speed of each liquid crystal panel based on data detected from a wind speed detection means.