JPH11119216A - Liquid crystal display - Google Patents

Abstract

PROBLEM TO BE SOLVED: To uniformize the heat distribution on the whole surface of a liquid crystal panel and the lightness of a display screen by effectively radiating heat generated in a light source to the rear of the panel. SOLUTION: A chassis panel 12 is arranged holding a gap of fixed width in between opposed to the approximately whole surface of the rear of a liquid crystal module 11. The panel 12 is brought into contact with a part near a part opposed to the light source 9 on the rear of the module 11 through a contact member 21. The part opposed to the light source 9 on the rear of the module 11 is directly heated to a high temperature by the light source 9 and the heat is transmitted to the panel 12 through the member 21 and cooled. A part not to be opposed to the light source 9 on the rear of the module 11 is heated by heat transmission from the part opposed to the light source 9 and heat radiation from the panel 12. Consequently, a temperature difference between the part opposed to the light source 9 on the rear of the module 11 and the part not to be opposed is reduced and the lightness of the display screen of the liquid crystal panel 5 is uniformized.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention displays an image by changing the arrangement of molecules having optical anisotropy by applying a voltage and selectively transmitting or blocking a backlight emitted from a light source. Related to liquid crystal displays.

[0002]

2. Description of the Related Art In a liquid crystal display having a relatively large display area, in order to improve the visibility of a displayed image, a position facing the rear surface of the liquid crystal panel or a position opposite to the rear surface of the liquid crystal panel is adopted. A liquid crystal module provided with a light source for irradiating a backlight to a position not facing the back surface is used. When the light source is placed at a position facing the back of the liquid crystal panel, the backlight emitted from the light source is passed only through the diffusion plate, and when the light source is placed at a position not facing the back of the liquid crystal panel, Light is distributed to the back surface of the liquid crystal panel via the diffusion plate, and the backlight is selectively transmitted or blocked by the liquid crystal panel. As a light source for the backlight, a cold cathode tube is generally used.

However, when the light source disposed on the rear side of the liquid crystal panel generates heat by driving, the heat distribution on the liquid crystal panel surface becomes uneven, and the display state on the liquid crystal panel surface becomes non-uniform. Decrease. In particular, in a liquid crystal display of a simple matrix drive system (STN, DSTN), it is known that if a temperature non-uniformity of ± 5 degrees or more occurs on the liquid crystal panel surface, the brightness of a display screen becomes non-uniform.

Therefore, in a conventional liquid crystal display, a chassis panel having a heat radiation function is closely attached to substantially the entire back surface of the liquid crystal module so that heat generated in the light source is radiated to the rear side of the liquid crystal module via the chassis panel. I have to. This chassis panel is formed in a substantially flat shape using a metal plate having excellent thermal conductivity as a raw material.

[0005]

However, in a conventional liquid crystal display in which a chassis panel having a heat radiation function is closely attached to substantially the entire back surface of the liquid crystal module, heat generated in the light source is effectively transmitted to the rear side of the liquid crystal module. However, the heat distribution cannot be made uniform over the entire surface of the liquid crystal panel, and there is a problem that the display state on the liquid crystal panel surface becomes non-uniform and the visibility of the displayed image decreases.

SUMMARY OF THE INVENTION It is an object of the present invention to dissipate heat generated in a light source to the rear side of a liquid crystal module effectively by arranging a heat radiating plate on the rear side of the liquid crystal module via an air layer, and to radiate heat to the entire surface of the liquid crystal panel. It is an object of the present invention to provide a liquid crystal display which can make the heat distribution uniform and the brightness of the display screen uniform.

[0007]

According to a first aspect of the present invention, there is provided a liquid crystal display having a liquid crystal module in which a light source for illuminating a backlight is disposed on a rear side of a liquid crystal panel. It is characterized in that a heat radiating plate is provided so as to face the light source on the rear surface of the liquid crystal module and to be in contact with the light source in the vicinity of the portion facing the light source.

According to the first aspect of the present invention, a gap having a constant width is formed so as to oppose substantially the entire back surface of the liquid crystal module, and a heat sink is disposed on the back surface of the gap. Also,
The heat radiating plate contacts the vicinity of the portion facing the light source on the back surface of the liquid crystal module. Therefore, the portion facing the light source on the back surface of the liquid crystal module is directly heated by the light source to a high temperature, and the heat is conducted to the heat radiating plate to be cooled. Further, a portion of the rear surface of the liquid crystal module that does not face the light source is heated by heat conduction from the portion facing the light source and heat radiation from the heat sink. Therefore, the temperature difference between the portion facing the light source and the portion not facing the light source on the back surface of the liquid crystal module becomes small, and the heat distribution becomes substantially uniform over the entire liquid crystal panel, and the brightness of the display screen becomes uniform.

The invention described in claim 2 is characterized in that a ventilation path is formed in the heat sink through a part of a gap near the light source.

According to the second aspect of the present invention, air flows into the gap formed on the back surface of the liquid crystal module near the portion facing the light source via the heat sink. Therefore, the portion of the rear surface of the liquid crystal module that is directly heated by the light source and becomes high temperature is cooled by the inflow of air in addition to the heat conduction to the heat sink, and the portion of the rear surface of the liquid crystal module that does not face the light source. Is further reduced, and the temperature distribution is further uniformed over the entire surface of the liquid crystal panel.

According to a third aspect of the present invention, the light source is disposed near at least one side surface of the liquid crystal module.
A heat conductive member is provided for bringing the vicinity of the side surface on the front surface of the liquid crystal module into contact with the heat sink.

According to the third aspect of the invention, the heat of the portion facing the light source on the front surface of the liquid crystal module is conducted to the heat radiating plate via the heat conducting member. Therefore, the portion of the front surface of the liquid crystal module which is directly heated by the light source and becomes high temperature is cooled by heat conduction to the heat radiating plate, and the temperature difference between the portion facing the light source and the portion not facing the light source in the entire liquid crystal module is further reduced. In addition, the temperature distribution is further uniformed over the entire surface of the liquid crystal panel.

[0013]

FIG. 1 is a view showing the appearance of a liquid crystal display according to an embodiment of the present invention. FIG. 1 (A) is a front view of the liquid crystal display, and FIG. 1 (B) is a side view of the liquid crystal display. It is. The liquid crystal display 1 is configured such that a main body 2 including a front cover 2a and a rear cover 2b is supported by a stand 3. Front cover 2
An opening 4 through which the liquid crystal panel 5 is exposed is formed on the front surface of the panel a. Below the front surface of the front cover 2a, a brightness adjustment knob 6 for adjusting the brightness of the liquid crystal panel 5, a contrast adjustment knob 7 for adjusting the contrast of the liquid crystal panel 5, and a power lamp 8 for displaying a power on / off state. Is exposed. Front cover 2a and rear cover 2
The main body 2 integrated with the body b is supported at the upper end of the stand 3 so as to be rotatable within a predetermined range around a horizontal rotation axis.

FIG. 2 is an assembly view of the liquid crystal display. A liquid crystal module 1 is provided inside the main body 2 that forms a housing with the front cover 2a and the rear cover 2b.
1, the module chassis panel 12, the printed wiring board 13, the board chassis panel 14, and the like are stored.
The liquid crystal module 11 houses the liquid crystal panel 5 exposed on the front surface, and horizontally stores a light source 9 for backlight, such as a cold cathode tube, near the upper and lower ends.

The module chassis panel 12 is formed by pressing a metal plate having excellent thermal conductivity by pressing or the like, and faces the entire rear surface of the liquid crystal module 11. A circuit for driving the liquid crystal panel 5 and the backlight 9 accommodated in the liquid crystal module 11 is formed on the printed wiring board 13. The printed wiring board 13 is attached to the board chassis panel 14 via the connection frame 15, and further attached to the back of the module chassis panel 12 via the board chassis panel 14.

A substantially U-shaped thin plate-shaped packing 16 contacts the upper and lower ends of the front surface of the liquid crystal module 11, and a substantially U-shaped thin plate frame 17 contacts the front surface of the packing 16. Touch The packing 16 is made of rubber having excellent heat conductivity, and the frame 17 is made of metal having excellent heat conductivity. The frame 17 is screwed to the module chassis panel 12 above and below the liquid crystal module 11. At this time, the packing 16 is sandwiched between the front surface of the liquid crystal module 11 and the frame 17.

An exhaust port 18 is formed in the upper part of the rear surface of the rear cover 2b, and a cooling fan is mounted on the inner surface of the rear cover 2b at a position facing the exhaust port 18. The cooling fan exhausts the heat inside the main body 2 to the outside via the exhaust port 18.

FIG. 3 is a diagram showing a configuration of a main part of the liquid crystal display. FIG. 2 is a perspective sectional view showing the vicinity of the upper end of the liquid crystal module 11 in a state where the module chassis panel 12, the packing 16 and the frame 17 are mounted. The upper end of the liquid crystal module 11 in which the liquid crystal panel 5 is stored on the front side inside is sandwiched between the module chassis panel 12 on the back side and the packing 16 and the frame 17 on the front side. That is, the module chassis panel 12 and the frame 17 are
a and 17a are fixed in a state of being in contact with the upper surface of the liquid crystal module 11.

In this state, the vertical surface 12 of the module chassis panel 12 is
b face each other with a certain gap. A flat contact member 21 is fixed to the front surface of the vertical surface 12b of the module chassis panel 12 over the entire length in the horizontal direction.
The contact member 21 contacts the rear surface of the liquid crystal module 11 at the upper end 21a. Inside the liquid crystal module 11, the light source 9 is arranged inside a portion where the upper end portion 21a of the contact member 21 contacts. A large number of openings 22 are formed in the vertical surface 12b of the module chassis panel 12 above the mounting position of the contact member 21 and in the horizontal surface 12c.

The lower end of the liquid crystal module 11 is configured to be vertically symmetrical with respect to the configuration shown in FIG.

FIG. 4 is a view showing a state of heating and heat radiation on the back side of the liquid crystal module of the liquid crystal display. The portion facing the light source 9 on the rear surface of the liquid crystal module 11 is directly heated by the light source 9 to a high temperature, and the heat is transmitted to the module chassis panel 12 via the contact member 21 and cooled. On the other hand, since the module chassis panel 12 does not directly contact a portion of the rear surface of the liquid crystal module 11 that does not face the light source 9, this portion has heat conduction from the portion facing the light source 9 and a module chassis. It is heated by heat radiation from panel 12. For this reason, the temperature difference between the portion facing the light source 9 and the portion not facing the light source 9 on the back surface of the liquid crystal module 11 is reduced, and the heat distribution over the entire surface of the liquid crystal panel 5 housed on the front side inside the liquid crystal module 11 is made substantially uniform. The brightness of the display screen on the liquid crystal panel 5 can be made uniform.

The upper and lower ends of the rear surface of the liquid crystal module 11 which are directly heated by the light source 9 and have a high temperature,
In addition to heat conduction to the module chassis panel 12,
Opening hole 2 formed in module chassis panel 12
2, the temperature difference between the portion facing the light source 9 and the portion not facing the light source 9 on the back surface of the liquid crystal module 11 is further reduced, and the heat distribution over the entire surface of the liquid crystal panel 5 is made more uniform. be able to.

Further, the upper and lower ends of the front surface of the liquid crystal module 11, which are directly heated by the light source 9 and have a high temperature, are cooled by heat conduction to the module chassis panel 12 through the packing 16 and the frame 17, and
In the entire liquid crystal module 11, the temperature difference between the portion facing the light source 9 and the portion not facing the light source 9 is further reduced, and the heat distribution over the entire surface of the liquid crystal panel 5 can be made more uniform.

In the liquid crystal display according to this embodiment, the light sources 9 are arranged one by one near the upper and lower ends of the liquid crystal module 11, but the number of light sources 9 and the arrangement position are not limited thereto. Absent.

In the liquid crystal display according to this embodiment, the light source 9 is disposed at a position facing a part of the rear surface of the liquid crystal panel 5, but the light source 9 is disposed at a position not facing the rear surface of the liquid crystal panel 5. The present invention can be similarly applied to a liquid crystal display configured to distribute light to the rear surface of the liquid crystal panel 5 via the light guide plate, and the light is generated on the liquid crystal panel surface according to the distance from the light source. The brightness of the display screen can be made uniform by eliminating the unevenness of the heat distribution.

[0026]

According to the first aspect of the present invention, a gap having a constant width is formed to face substantially the entire back surface of the liquid crystal module, and a radiator plate is disposed on the back surface of the gap. By contacting the area near the part facing the light source on the back side of the module, the part that is directly heated by the light source on the back side of the liquid crystal module and becomes high temperature is cooled via the heat sink, and at the back side of the liquid crystal module it faces the light source. The part not to be heated by the heat conduction from the part facing the light source, and the heat radiation from the radiator plate, can reduce the temperature difference between the part facing the light source and the part not facing the light source on the back of the liquid crystal module,
It is possible to make the heat distribution uniform over the entire surface of the liquid crystal panel, make the brightness of the display screen uniform, and prevent the visibility of the displayed image from lowering.

According to the second aspect of the present invention, air is caused to flow through the heat radiating plate near the portion facing the light source in the gap on the back surface of the liquid crystal module, so that the light source directly contacts the rear surface of the liquid crystal module. In addition to heat conduction to the heat sink, the heated portion is cooled by the inflow of air, so that the temperature difference between the portion facing the light source and the portion not facing the light source on the back of the liquid crystal module can be further reduced. The heat distribution over the entire surface of the liquid crystal panel can be made more uniform, and the brightness of the display screen can be made more uniform.

According to the third aspect of the invention, the heat of the portion facing the light source on the front surface of the liquid crystal module is conducted to the heat radiating plate via the heat conducting member, so that the light source directly heats the front surface of the liquid crystal module. The high temperature part is cooled by heat conduction to the radiator plate, so that the temperature difference between the part facing the light source and the part not facing the light source can be further reduced in the entire liquid crystal module, and the heat distribution over the entire liquid crystal panel can be reduced. Further, the brightness of the display screen can be made more uniform.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating an appearance of a liquid crystal display according to an embodiment of the present invention.

FIG. 2 is an assembly view of the liquid crystal display.

FIG. 3 is a diagram showing a configuration of a main part of the liquid crystal display.

FIG. 4 is a diagram showing a state of heating and heat radiation on the back side of the liquid crystal module of the liquid crystal display.

[Explanation of symbols]

 1-Liquid crystal display 2-Main unit 2a-Front cover 2b-Rear cover 5-Liquid crystal panel 9-Light source 11-Liquid crystal module 12-Module chassis panel (heat radiating plate) 16-Packing 17-Frame (Heat conductive member) 21-Contact member 22-opening

Claims (3)

[Claims] 1. A liquid crystal display comprising a liquid crystal module in which a light source for illuminating a backlight is disposed on the back side of a liquid crystal panel. A liquid crystal display comprising a heat radiating plate disposed in contact with a portion of a rear surface facing a light source. 2. The liquid crystal display according to claim 1, wherein an air passage passing through a part of the gap near the light source is formed in the heat sink. 3. The liquid crystal module according to claim 1, wherein the light source is disposed near at least one side surface of the liquid crystal module, and a heat conducting member is provided for bringing the vicinity of the side surface on the front surface of the liquid crystal module into contact with a heat sink. LCD display.