JP6907039B2 - Display device - Google Patents

Description

The present invention relates to a display device including a fan that cools a display module that displays an image.

In recent years, there is a display device capable of displaying an image in a dynamic range (High Dynamic Range: HDR) including higher brightness than before. For example, when the display device uses a display module consisting of a backlight and a liquid crystal panel, in order to increase the maximum brightness to be displayed, it is necessary to operate the backlight so as to irradiate light with higher brightness than before. ..

As the brightness of the backlight increases, the amount of heat generated from the control board for driving the light source may increase. The control board is a printed circuit board on which electronic components such as a transformer and a driver IC are mounted. Therefore, in the vicinity of the control board, the distribution of air resistance due to unevenness due to electronic components is large. Therefore, it may be difficult to improve the cooling performance of the control board.

In Patent Document 1, in a projector for forced air cooling by a fan, a first flow path that sucks outside air from a suction port and discharges it from the discharge port to the outside of a housing and a second flow path that circulates inside the housing are provided. , It is disclosed that the efficiency is improved by switching by the wind direction adjusting plate.

Japanese Unexamined Patent Publication No. 2009-122483

However, in the technique disclosed in Patent Document 1, a complicated mechanism is required because the flow path is switched by moving the wind direction rectifying plate by the actuator.

Therefore, an object of the present invention is to provide a display device capable of efficiently dissipating heat and cooling a control board for operating a display module.

In order to solve the above-mentioned problems, the display device of the present invention includes a display module for displaying an image on the front side, a first fan provided on the back side of the display module for cooling the display module, and the display module. A power supply provided on the back side of the display module and the first fan for supplying power to the display module, a control board for controlling the display module and the first fan, and the back surface of the display module. A space in which the first fan, an exterior member accommodating the control board, and the first fan are installed and covered with the exterior member and the back surface of the display module is provided with the control board. The first fan includes a partition plate that divides one space into a second space including the back surface of the display module, and the first fan sends air from the first space to the second space. The exterior member is provided between the space and the second space, and the exterior member includes a first opening and a second opening connecting the first space and the outside of the exterior member, and the second space and the exterior member. Has a third opening, which connects to the outside of the
When the control board is cooled in the first cooling mode, the control board operates the first fan at a rotation speed higher than a predetermined rotation speed, and cools the control board in the second cooling mode. In this case, when the first fan is controlled in the first cooling mode by operating the first fan at a rotation speed equal to or lower than a predetermined rotation speed, the air flowing in from the first opening is said to be the same. By passing in the vicinity of the control board and discharging most of the heat from the third opening through the first fan, the heat generated in the control board is discharged to the outside of the exterior member, and the second When the first fan is controlled in the cooling mode of the above, the air flowing in from the first opening passes in the vicinity of the control board, and most of the air is discharged from the second opening. It is characterized in that the heat generated in the substrate is discharged to the outside of the exterior member .

According to the present invention, the fan for cooling the display module makes it possible to switch the flow rate of air passing in the vicinity of the control board without requiring a complicated mechanism and control. Therefore, it is possible to efficiently dissipate heat and cool the control board for operating the display module.

It is an exploded perspective view which shows the structure of a display module. It is a first cross-sectional view of an image display device. It is a 1st schematic diagram which shows the flow path of an image display device. It is a second sectional view of the image display device. It is a 2nd schematic diagram which shows the flow path of an image display device. It is a third sectional view of the image display device. It is a 3rd schematic diagram which shows the flow path of an image display device. It is a fourth sectional view of the image display device. It is a 4th schematic diagram which shows the flow path of an image display device. FIG. 5 is a fifth cross-sectional view of the image display device. It is a 5th schematic diagram which shows the flow path of an image display device.

[Example 1]
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is an exploded perspective view showing a configuration of a display module 13 in the display device 1 according to the first embodiment of the present invention. The display module 13 is a liquid crystal display module including a liquid crystal panel 2 and a backlight 4 and displaying an image on the front side. The liquid crystal panel 2 is a display panel that modulates the light emitted from the backlight 4 and displays an image on the screen.

In the image display device 1, a bezel 3 is arranged on the front side of the liquid crystal panel 2, and a backlight 4 is arranged on the back side. The backlight 4 includes a case 8 to which a light source substrate 5, a drive substrate 6 (not shown in FIG. 1), and a heat sink 7 (not shown in FIG. 1) are attached.

In recent years, the light source substrate 5 often uses an LED 9 as a light source, but the light source is not limited to this, and a CCFL (Cold Cathode Fluorescent Lamp) or the like may be used. On the liquid crystal panel 2 side of the case 8, a reflective sheet 10 for efficiently reflecting the light diffused from the light source substrate 5 to the liquid crystal panel 2 is arranged. On the liquid crystal panel 2 side of the case 8, optical sheets 11 for eliminating light unevenness and improving brightness by diffusing and condensing light are arranged. On the liquid crystal panel 2 side of the optical sheets 11, a panel holder 12 that holds the optical sheets 11 and supports the liquid crystal panel 2 from the back side is arranged. The liquid crystal panel 2 has light transmittance, and in this way, the light from the backlight 4 is efficiently emitted, and the light is transmitted through the liquid crystal panel 2 to display an image on the liquid crystal panel 2.

On the back side of the case 8, a plurality of heat sinks 7 are fixed in a state of being thermally adhered to the case 8 with a heat conductive member (not shown) interposed therebetween, and heat generated by the light source substrate 5 passes through the heat sink 7. It is released into the space on the back side. There is no inconvenience even if the case 8 and the heat sink 7 are integrally formed.

As described above, the display module 13 is configured by adding the drive board 6 and the heat sink 7 from the bezel 3 shown in FIG. 1 to the backlight 4 including the liquid crystal panel 2, and the display module 13 is the second heat source referred to in the present invention. Is. Specific electronic devices as heating elements are a liquid crystal panel 2, a light source substrate 5 including an LED 9, and a drive substrate 6, but the display module 13 is generally a second heat source to be cooled and dissipated.

FIG. 2 is a cross-sectional view of the image display device 1 according to the first embodiment of the present invention. It is assumed that the image display device 1 is installed so that the screen of the display module 13 is parallel to the vertical direction at the time of use. Therefore, the subsequent vertical positions mean the vertical directions during use.

In the present invention, the first heat source is a power supply 14 that supplies an electric current to the display module 13 that is the second heat source to operate the display module 13. The power supply 14 is installed on the power supply board 26. Further, the power supply 14 is provided on the back side of the display module 13 and the fan 16 described later.

The cover 15 is an exterior member that houses the back surface of the display module 13, the power supply 14, the fan 16, and the control board 17. The cover 15 also accommodates an image processing board 18 (not shown in FIG. 2) that receives an image signal from an external device and transmits the image signal to the display module 13.

In the first embodiment, the power supply 14 is attached to the power supply board 26 in a horizontally long position so as not to impair the thinness of the image display device 1 in the side sectional view of FIG. 2, and is arranged at the lowermost portion. The control board 17 and the image processing board 18 are attached to the other side of the paper surface of the power supply 14 in FIG. The control board 17 and the image processing board 18 are also a type of heat source, and it can be said that the first heat source including the power supply 14 is composed of a plurality of heat sources. First, the heat sources to be cooled and dissipated are the power supply 14 and the display module 13. Is.

Further, the space covered by the cover 15 and the back surface of the display module 13 includes the second heat source space 21 including the back surface of the display module 13 and the power supply 14 on the back side of the second heat source space 21 by the partition plate 19. It is divided into a first heat source space 20 and. It is assumed that the partition plate 19 is installed so as to be parallel to the screen of the display module 13 in the vertical direction. The partition plate 19 may not be arranged in parallel with the display module 13, but may be arranged diagonally with respect to the back surface of the display module 13. Further, the partition plate 19 may be a metal plate formed so as to function as a chassis in which the power supply board 26 is arranged.

The first heat source space 20 side of the cover 15 is provided with a first vent 22 and a second vent 23 connecting the first heat source space 20 and the outside of the cover 15, and the second heat source space 21 side is provided with a first vent 22 and a second vent 23. A third vent 24 is provided to connect the second heat source space 21 to the outside of the cover 15.

The first vent 22 is provided below the power supply 14 and at the rearmost part of the cover 15. The second vent 23 is provided at a diagonal position of the first vent 22 in the first heat source space 20, that is, above the power supply 14 and in front of the cover 15. As shown in FIG. 2, the second vent 23 is provided close to the partition plate 19.

The third vent 24 is provided on the upper part of the cover 15. The first vent 22 may be provided on the back surface of the cover 15 shown in FIG. 2 instead of the bottom surface, and the third vent 24 may be provided on the top surface of the cover 15 shown in FIG. 2 instead of the back surface. It doesn't matter.

The fan 16 is attached to the partition plate 19, and the stop / drive and the rotation speed are controlled by a signal sent from the control board 17. The fan 16 is first provided to cool and dissipate heat from the display module 13, and is arranged below the second heat source space 21 in the first embodiment. On the other hand, the fan 16 is provided so that its center position is equal to or above the power supply 14 when viewed from the back side of the display module 13. Further, the fan 16 is arranged in the vicinity of the second vent 23. Although the fan 16 is arranged on the second heat source space 21 side in FIG. 2, it may be arranged on the first heat application space 20 side.

FIG. 3 is a cross-sectional view showing a flow path of the image display device 1 shown in FIG. As shown in FIG. 3A, in the first flow path A, the first vent 22 serves as an outside air intake port of the first heat source space 20, and the second vent 23 serves as an external discharge port of the first heat source space 20. Is formed. The volume of the first vent 22 and the second vent 23 increases as the air taken in passes through the first heat source space 20. Therefore, the suction amount F1in of the first vent 22 and the discharge amount F2out of the second vent 23 are each provided with an opening area so that the relationship of F2out> F1in.

As shown in FIG. 3B, in the second flow path B, the second vent 23 is used as the outside air intake port of the second heat source space 21, and the third vent 24 is set as the second heat source space by the air blown by the fan 16. It is formed so as to be an external outlet of 21. As shown in FIG. 3C, in the third flow path C, the first vent 22 is used as the outside air intake port of the first heat source space 20, and the third vent 24 is set as the first heat source space by the air blown by the fan 16. It is formed so as to have 20 external outlets.

The intake air from the first vent 22 and the intake air from the second vent 23 are added together to form the exhaust from the third vent 24. As described above, when the air sucked from the outside passes through the first heat source space 20 and the second heat source space 21, the temperature rises and the volume increases. Therefore, the opening area of each vent is given and the maximum flow rate of the fan 16 is set so that the maximum discharge amount F3out_max of the third vent 24 satisfies the following equation 1.
F3out_max> F1in_max + F2in_max (Equation 1)

Here, the maximum suction amount F1in_max of the first vent 22 is shown. The maximum suction amount F2in_max of the second vent 23 indicates.

Although the schematic configuration of the first embodiment of the present invention has been described so far, the gist of the present invention will be described here. The present invention is a technique for improving the exhaust flow velocity by switching the flow path. More specifically, by increasing the speed of the fan 16, the discharge flow path on the first heat source space 20 side is moved from the second vent 23 provided on the first heat source space 20 side to the second heat source space 21 side. Switch to the provided third vent 24. This is characterized by improving the exhaust flow velocity of the first heat source space 20.

Here, increasing the speed of the fan 16 means controlling the fan 16 in a high-efficiency cooling mode in which the rotation speed of the fan 16 is higher than a predetermined rotation speed. The display device 1 disclosed in the first embodiment of the present invention includes a strong cooling mode in which the rotation speed of the fan 16 is higher than a predetermined rotation speed, and an energy saving cooling mode in which the rotation speed of the fan 16 is equal to or less than a predetermined rotation speed. It is possible to control the rotation of the fan 16 with. The air flow in the space inside the cover 15 in each cooling mode will be described.

Hereinafter, the three flow paths of the first embodiment of the present invention and the control of the fan 16 will be described in detail. The image transmitted from the image processing substrate 18 to the display module 13 is not always an HDR image, but includes various images such as an image having a standard dynamic range, a so-called SDR (Standard Dynamic Range) image.

When an image that does not require much brightness is transmitted to the backlight 4 and the liquid crystal panel 2 displays the image, the heat generated by the display module 13 is relatively small, and the heat generated by the power supply 14 is also relatively small. In such a state, the control board 17 operates the fan 16 in the energy-saving cooling mode. Specifically, the control board 17 stops the fan 16.

FIG. 3A shows the air flow in the space inside the cover 15 when the fan 16 is operated in the energy-saving cooling mode. The first vent 22 takes in air as an outside air intake port, and the air cools and dissipates heat from the power supply 14. Since the fan 16 is stopped, the blade 25 functions as a shielding member, and the air is discharged to the outside of the cover 15 using the vent 23 as an external discharge port without flowing to the second heat source space 21. That is, when the display module 13 has a low load, the fan 16 is stopped to dissipate the heat generated by the power supply 14 through the first flow path A.

When the control board 17 controls the display module 13 to display an image (HDR image) having a high dynamic range, the display module 13 and the power supply 14 generate a large amount of heat. In such a state, the control board 17 operates the fan 16 in the strong cooling mode. Specifically, the control board 17 rotates the fan 16 at high speed.

3 (b) and 3 (c) show the air flow in the space inside the cover 15 when the fan 16 is operated in the strong cooling mode. In FIG. 3B, the second vent 23 takes in air as an outside air intake port by the fan 16 rotating at high speed, and the air is sent to the second heat source space 21 to cool and dissipate the display module 13, and the third The air vent 24 is used as an external exhaust port and is discharged to the outside of the cover 15.

In FIG. 3C, the air taken in by using the first vent 22 as the outside air suction port is sent to the second heat source space 21 by the high-speed rotating fan 16 without being discharged from the second vent 23. , The vent 24 is used as an external discharge port and is discharged to the outside of the cover 15. That is, when the display module 13 has a high load, the fan 16 is rotated at high speed to switch the heat generated by the power supply 14 from the first flow path A to the third flow path C to dissipate heat. When the fan 16 is controlled in the strong cooling mode by the above-mentioned control, the air flowing in from the first vent 22 passes in the vicinity of the power supply 14, and most of the air passes through the fan 16 to the third vent 24. The heat generated by the power supply 14 is discharged by being discharged from the power source 14. Further, when the fan 16 is controlled in the energy-saving cooling mode, the air flowing in from the first vent 22 passes near the power supply 14, and most of the air is discharged from the second vent 23 to power the power supply. The heat generated in No. 14 is discharged to the outside.

Here, when the fan 16 is operated in the strong cooling mode, the flow rate of the air flowing into the first heat source space 20 from the second vent 23 is larger than that in the energy saving cooling mode. Further, the flow rate of the air flowing into the first heat source space 20 from the first vent 22 is larger when the fan 16 is operated in the strong cooling mode than when the fan 16 is operated in the energy saving cooling mode. The flow rate of the air discharged from the third vent 24 in the strong cooling mode is larger than the flow rate of the air discharged from the second vent 23 and the third vent 24 in the energy saving cooling mode. Therefore, the flow rate and the flow velocity of the air flowing in the vicinity of the power source 14 are larger (faster) in the strong cooling mode than in the energy saving cooling mode. As a result, the exhaust flow velocity of the first heat source space 20 is improved. Therefore, the cooling efficiency of the power supply 14 increases. Then, by rotating the fan 16 at high speed, the heat generated by the display module 13 is discharged by the second flow path B.

That is, the control board 17 operates the fan 16 in the strong cooling mode when the display module 13 is controlled in the high brightness display mode so that the image is displayed with high brightness. If this is not the case, the control board 17 operates the fan 16 in the energy-saving cooling mode. Specifically, the case where the image is displayed with high brightness is the case where the image is displayed at the upper limit value of the display brightness higher than 100 nits.

For example, it is assumed that the control board 17 can control the display control mode of the display module 13 in either the HDR display mode for displaying the HDR image or the SDR display mode for displaying the SDR image. When the display module 13 is controlled in the HDR display mode, the control board 17 operates the fan 16 in the strong cooling mode. Further, when the display module 13 is controlled in the SDR display mode, the control board 17 operates the fan 16 in the energy saving cooling mode.

The relationship between the display control mode of the display module 13 and the cooling mode is not limited to the above. A plurality of high-luminance display modes may be set. For example, when displaying an image with an upper limit of display brightness higher than 1000 nits, the fan 16 is operated in the strong cooling mode. Even if the fan 16 is operated at a rotation speed between the rotation speed of the strong cooling mode and the rotation speed of the energy saving cooling mode when displaying an image with a brightness higher than 100 nits and 1000 nits or less as the upper limit of the display brightness. good.

When an image with medium brightness required for the backlight 4 is transmitted from the image processing substrate 18 to the display module 13 and the liquid crystal panel 2 displays the image, the second vent 23 is the first heat source space 20. It also has the functions of the external exhaust port of the above and the outside air intake port of the second heat source space 21. In other words, when the fan 16 is driven in an intermediate state from the stopped state to the high-speed rotation, the second vent 23 functions as an external exhaust port of the first heat source space 20 and an outside air intake port of the second heat source space 21. Also have.

If the fan 16 has a very low speed, both exhaust and suction are performed at the second vent 23, the air in the first heat source space 20 is discharged from the second vent 23, and a part of the air is discharged from the second heat source. It is sent to space 21. If the fan 16 has a relatively high speed, the fan 16 is hardly discharged from the second vent 23 and is mainly sucked, and most of the air in the first heat source space 20 is sent to the second heat source space 21.

Embodiment 1 of the present invention does not necessarily require a temperature sensor as a temperature detecting means in the display module 13, the power supply 14, the first heat source space 20, and the second heat source space 21. This is because the first heat source is the power supply 14, and the second heat source is the display module 13 that operates by receiving a current supply from the power supply 14. When the display module 13 becomes hot, the power supply 14 inevitably becomes hot. Therefore, depending on what kind of image is transmitted from the image processing board 18 to the display module 13, how much current the power supply 14 supplies to the display module 13 and how much the temperature of the display module 13 and the power supply 14 rises. , You can create a database in advance. Based on the data, the control board 17 determines the stop / drive and the rotation speed of the fan 16.

An intake fan as a ventilation means may be attached to the inside of the first vent 22. However, the fan cannot be mounted inside the second vent 23. This is because it becomes difficult to switch between inhalation and discharge, and coexistence of inhalation and discharge is established, or on the contrary, it becomes inefficient.

As described above, according to the structure of the first embodiment of the present invention, when an image requesting high brightness from the backlight 4 is transmitted to the display module 13, the fan 16 on the backlight 4 side is operated in the strong cooling mode. To control. As a result, the exhaust flow path on the power supply 14 side can be switched from the second vent 23 to the third vent 24, and the exhaust flow velocity on the power supply 14 side can be improved. Therefore, it is possible to switch between the flow path and the exhaust port without the need for complicated mechanism and control, and it is possible to efficiently dissipate and cool the power supply 14 without the need to add a fan to improve the exhaust flow velocity. become.

[Example 2]
Hereinafter, FIG. 4 is a cross-sectional view of the image display device 1 according to the second embodiment of the present invention. FIG. 5 is a cross-sectional view showing a flow path of the image display device 1 shown in FIG. In FIGS. 4 and 5, the description of the parts common to the first embodiment will be omitted.

In the side sectional view of FIG. 4, the power supply 14 has a power supply board 26 mounted in parallel with the display module 13 and the partition plate 19 and is arranged below the first heat source space 20. This is because the fan 16 is mounted at a position that is substantially in the center of the partition plate 19 and faces the central portion of the display module 13. The second vent 23 is provided in the vicinity of the fan 16 at a higher position than that of the first embodiment of the present invention.

The reason why the fan 16 is arranged in this way is that many of the liquid crystal panels 2 tend to have a high temperature in the central portion when viewed from the front. As a spray fan that blows air at a position facing the central portion of the display module 13 in a direction substantially perpendicular to the display module 13 in order to intensively cool and dissipate heat in the central portion of the display module 13. It depends on the setting. Therefore, the power supply 14 and the second vent 23 also follow the fan 16 and are arranged as described above.

The second vent 23 is provided so as to be inclined with respect to the cover 15 in order to place importance on taking in outside air into the display module 13 as compared with the first embodiment of the present invention. The third vent 24 is provided on the top surface and the bottom surface of the cover 15 because the fan 16 is a spray fan.

By arranging the power supply 14, the fan 16, and the second vent 23 as described above, the liquid crystal panel 2 whose heat generation distribution is biased toward the center, the display module on which the power supply 14 is mounted, and the power supply 14 can be efficiently dissipated and cooled. Becomes possible.

[Example 3]
Hereinafter, FIG. 6 is a cross-sectional view of the image display device 1 according to the third embodiment of the present invention. FIG. 7 is a cross-sectional view showing a flow path of the image display device 1 shown in FIG. In FIGS. 6 and 7, the description of common parts with the first and second embodiments will be omitted.

The advantage of using the LED 9 as the light source of the backlight 4 instead of the CCFL is that the amount of light of the light source can be adjusted individually. High image quality and power saving are realized by a method called local dimming in which the LED 9 is divided into a plurality of areas and the LED 9 is driven with the brightness required by the image for each area. The backlight 4 of the present invention is a direct type backlight using an LED 9 as a light source, and it is easy to adopt a local dimming method. These techniques provide an image display device 1 equipped with a 4K or 8K high-definition liquid crystal panel 2 and a backlight 4 that enables high-brightness HDR.

In Embodiment 3 of the present invention, the arrangement of the fan 16 corresponding to the display module 13 controlled for each region will be described. The fan 16 of the first and second embodiments is referred to as a first fan 16 in the third embodiment.

As shown in FIG. 6, the first fan 16 is composed of a plurality of the first fans 16 and is arranged substantially parallel to and substantially in the same plane as the display module 13 and substantially uniformly in the vertical and horizontal directions. Each of the first fans 16 has a control region capable of controlling the temperature of the display module 13. Further, the backlight 4 can control the irradiance brightness for each of a plurality of display areas obtained by dividing the screen. As shown in FIG. 6, the first fan 16 is provided so that the control area of each first fan 16 corresponds to two or more display areas. In addition, the same number as the number of display areas may be provided by using a small fan so that the control area of each first fan 16 corresponds to the display area. The first fan 16 is provided as a spray fan as in the second embodiment, because a plurality of the first fans 16 are arranged on the back surface of the display module 13. Although not shown in FIG. 6, the first fans 16 are arranged in a plurality of rows in the vertical direction of the paper surface and in the horizontal direction when viewed from the front of the image display device 1, but three fans 16 are arranged vertically as shown in the drawing. The number is not limited.

The first fan 16 forming the second flow path B and the third flow path C has a height equal to or higher than that of the power source 14 which is the first heat source, and is attached and used in the vicinity of the second vent 24. NS. That is, the first fan 16 forming the second flow path B and the third flow path C is at least one or more first fans 16 located at the uppermost portion of the plurality of first fans 16.

The power supply 14 has a higher output and a larger size than the first and second embodiments in order to cope with higher brightness, and the volume of the first heat source space 20 including the power supply 14 is also expanded. As a further countermeasure, in the third embodiment, a second fan 27 for sucking outside air is attached as a ventilation means inside the first vent 22 at the lower part of the first heat source space 20.

The first heat source space 20 is provided with a second partition plate 30 that divides the first heat source space 20 into a power supply space 28 and an intake space 29 that takes in air into the second heat source space 21. The power supply space 28 and the intake space 29 are subspaces in which the first heat source space 20 is divided. The second partition plate 30 is provided so that the second vent 23 is located on the intake space 29 side, and the second partition plate 30 has a first flow path at a position facing the first fan 16 at the uppermost portion. A relay opening 31 is provided to form A and the third flow path C.

A fourth vent 32 is provided on the intake space 29 side of the cover 15, and a fifth vent 33 is provided on the second heat source space 21 side of the cover 15. As shown in FIG. 7B, in the fourth flow path D, the fourth vent 32 is used as the outside air intake port of the second heat source space 21, and the fifth is blown by the first fan 16 located at a position other than the uppermost portion. The vent 33 is formed so as to serve as an external discharge port of the second heat source space 21. That is, when the first fan 16 located at a position other than the uppermost portion is rotating, the air outside the cover 15 flowing in from the fourth vent 32 passes through the first fan 16 located at a position other than the uppermost portion. It is discharged from the fifth vent 33.

On the light source substrate 5, a plurality of first temperature sensors 34 for detecting the temperature of the display module 13 are mounted on the second heat source space 21 side at positions facing the center of the plurality of first fans 16. The first temperature sensor 34 is mounted directly behind the LED 9, and the detected value of the first temperature sensor 34 is a value approximately corresponding to the temperature of the LED 9, which is a light source in the display module 13. Further, on the first partition plate 19, a second temperature sensor 35 that detects the temperature of the outside air sucked from the fourth vent 32 is attached to the inside of the fourth vent 32. The detected value of the second temperature sensor 35 is a value corresponding to the temperature (outside air temperature) of the outside air sucked from the fourth vent 32. A thermistor, a thermocouple, or the like is used as the first temperature sensor 34 and the second temperature sensor 35, and the present invention is not limited thereto.

Hereinafter, the control of the first fan 16 and the second fan 27 will be described in detail. The control board 17 determines the brightness level of the image signal in the display area corresponding to each control area. The brightness level of the image signal in the display area corresponding to each control area is defined as the brightness level of each control area. The control board 17 controls the stop, drive, and rotation speed of the corresponding first fan 16 based on the brightness level of each control region.

As an example, some threshold values are stored in advance on the control board 17, and when a video signal having a low brightness level equal to or lower than the first threshold value is transmitted, the control board 17 corresponds to the control region. Stop the fan 16. Further, when a video signal having a high brightness level equal to or higher than the second threshold value is transmitted, the control board 17 drives the first fan 16 corresponding to the control region at the set maximum rotation speed. Further, various brightness levels and the corresponding rotation speeds of the first fan 16 are stored in the control board 17 as a table, and the first fan 16 is driven at the optimum rotation speed based on the determined brightness level.

Not only the first fan 16 corresponding to the control region but also the surrounding first fans 16 are coordinatedly controlled. In particular, since the temperature of the power supply 14 rises not only in the brightness level of the opposite control region but also in the brightness level of the other control region of the first fan 16 at the top, the heat load in the entire control region is comprehensively determined. And be controlled.

The second fan 27 is constantly driven because the first fan 16 is sufficiently ventilated in a large volume first heat source space even when the first fan 16 is stopped or at a low speed, and because the first flow path A is long.

The image display device 1 of the first and second embodiments did not have a temperature sensor. However, in the third embodiment, in the image display device 1 which is equipped with a 4K or 8K high-definition liquid crystal panel 2 and a backlight 4 which enables high-brightness HDR and employs a local dimming method, more precise temperature control can be performed. Desired. Above all, such an image display device 1 needs to withstand professional use in a broadcasting station or a video production site. The control board 17 controls the stop, drive, and rotation speed of all the first fans 16 based on the outside air temperature acquired from the second temperature sensor 35 and the approximate temperature of the light source acquired from the first temperature sensor 34. The rotation speed of the second fan 27 is controlled.

Finally, the relationship between the four flow paths of the third embodiment of the present invention will be described. The first flow path A and the third flow path C function in the same manner as in the first and second embodiments. When the first fan 16, particularly the first fan 16 located at the uppermost part, is driven, heat dissipation / cooling of the first heat source space 20 is switched from the first flow path A to the third flow path C as the rotation speed increases. ..

When the first fan 16 other than the uppermost fan 16 is driven and the uppermost first fan 16 is stopped, the air passing through the opening 31 from the first heat source space 20 is not the second vent 23 or the uppermost portion. It is discharged from the fifth vent via the first fan 16. If it is determined from the outside air temperature, the image signal transmitted to the control region, and the approximate temperature of the LED 9 that it is necessary to suppress the temperature rise of the power supply 14, the control board 17 appropriately selects the first fan 16 at the top. It is driven at a high rotation speed.

As described above, by arranging the plurality of first fans 16 and newly providing the fourth vent 32 and the fifth vent 33 to form the fourth flow path D, the liquid crystal panel 2 and the LED 9 are efficiently dissipated in each region.・ Can be cooled. Then, a second fan 27 is provided, a first temperature sensor 34 and a second temperature sensor 35 are provided, and based on the detected values thereof, it is possible to efficiently dissipate and cool the power supply 14 having a high output and a large size. become.

[Example 4]
Hereinafter, FIG. 8 is a cross-sectional view of the image display device 1 according to the fourth embodiment of the present invention. FIG. 9 is a cross-sectional view showing a flow path of the image display device 1 shown in FIG.

The power supply 14 of the fourth embodiment is not only increased in output and size but also in a plurality of power sources in order to cope with further increase in brightness as compared with the previous embodiment 3. Further, the control of the display module 13 and the power supply 14 has become more sophisticated, the capacity of the image signal has increased, and the heat generated by the control board 17 and the image processing board 18 has also increased. Therefore, the fourth embodiment is characterized in that these are collectively housed in the first heat source space 20 to form a folded first flow path A that performs common heat dissipation and cooling.

The power supply space 28 is provided with a third partition plate 38 that divides the power supply space 28 into the space 36 and the space 37. The third partition plate 38 is provided with a second relay opening 39 forming the first flow path A at the lowermost portion, and the cover 15 has an upstream space 36 and a cover 15 on the back side of the second relay opening 39. A sixth vent 40 is provided to connect to the outside of the.

Since the first flow path A is longer than that of the third embodiment and is folded back, the second fan 27 is required and is always driven.

Since the temperature of the first flow path A rises as it goes downstream, outside air is replenished and taken in from the sixth vent 40 in order to sufficiently dissipate and cool the power supply 14.
When the uppermost first fan 16 is stopped, a part of the air taken in by the second fan 27 is discharged to the outside from the sixth vent 40.
When the uppermost first fan 16 is driven, the air taken in by the second fan 27 is pulled from the opening 31 to the intake space 29, and the outside air is also taken in from the sixth vent 40.

As described above, the third partition plate 38, the second opening 39, and the sixth vent 40 are provided for the first heat source space 20 having a large volume for accommodating the increased output, larger size, and multiple power sources 14. , The folded first flow path A is formed. As a result, the power supply 14 can be efficiently dissipated and cooled by utilizing the speed increase of the first fan.

[Implementation system 5]
Hereinafter, FIG. 10 is a cross-sectional view of the image display device 1 according to the fifth embodiment of the present invention. FIG. 11 is a cross-sectional view showing a flow path of the image display device 1 shown in FIG.

In the fifth embodiment, among the heat sources in the first heat generation space 20 described in the fourth embodiment, the heat sources having a relatively small relationship with the heat generation of the display module 13, that is, the control board 17 and the image processing board 18 are first flowed through. It dissipates heat and cools using a flow path different from that of A.

The power supply space 28 is provided with a fourth partition plate 43 that divides the power supply space 28 into a small space of the space 41 and the space 42. The fourth partition plate 43 is provided with a third relay opening 44 at the lowermost portion in the vicinity of the first vent 22. Further, the first vent is provided on the bottom surface of the power supply space 28. The second fan 27 is attached to the inside of the first vent 22 so as to straddle the third relay opening 44. The second fan 27 is arranged closer to the space 41 side so that the amount of air sent out to the space 41 is large. The cover 15 is provided with a seventh vent 45 at the uppermost portion on the space 42 side. The fifth flow path E is formed so that the first vent 22 serves as the external suction port of the space 42 and the seventh vent 45 serves as the external discharge port of the space 42 by the air blown by the second fan 27.

When the first fan is driven, only the air in the space 41 is drawn into the intake space 29 from the first opening 31 and discharged from the third vent 23.

By arranging the fourth partition plate 43, the third opening 44, the second fan 27, and the seventh vent as described above, the power supply 14 to be cooled and dissipated first from the first heat source space 20 can be more efficiently cooled. Can dissipate heat and cool.

1 Image display device 13 Display module 14 Power supply 15 Cover 16 Fan 17 Control board 19 Partition plate 20 First heat source space 21 Second heat source space 22 First vent 23 Second vent 24 Third vent

Claims (19)

A display module that displays an image on the front side,
A first fan provided on the back side of the display module and for cooling the display module,
A power supply provided on the back side of the display module and the first fan for supplying electric power to the display module, and
A control board for controlling the display module and the first fan,
An exterior member that houses the back surface of the display module, the first fan, and the control board.
A partition in which the first fan is installed and the space covered by the exterior member and the back surface of the display module is divided into a first space including the control board and a second space including the back surface of the display module. Board and
With
The first fan is provided between the first space and the second space so as to send the air in the first space to the second space.
The exterior member is
A first opening and a second opening connecting the first space and the outside of the exterior member,
It has a third opening that connects the second space and the outside of the exterior member.
The control board is
When the control board is cooled in the first cooling mode, the first fan is operated at a rotation speed higher than a predetermined rotation speed.
When the control board is cooled in the second cooling mode, the first fan is operated at a rotation speed equal to or lower than a predetermined rotation speed .
When the first fan is controlled in the first cooling mode, the air flowing in from the first opening passes in the vicinity of the control board, and most of the air passes through the first fan through the first fan. By being discharged from the opening, the heat generated in the control board is discharged to the outside of the exterior member, and the heat is discharged to the outside of the exterior member.
When the first fan is controlled in the second cooling mode, the air flowing in from the first opening passes in the vicinity of the control board, and most of the air is discharged from the second opening. , A display device characterized in that the heat generated in the control board is discharged to the outside of the exterior member. The display device according to claim 1, wherein the flow rate of air flowing into the first space from the second opening is larger in the first cooling mode than in the second cooling mode. The display according to claim 1 or 2, wherein the flow rate of air flowing into the first space from the first opening is larger in the first cooling mode than in the second cooling mode. Device. The flow rate of the air discharged from the third opening in the first cooling mode is larger than the flow rate of the air discharged from the second opening and the third opening in the second cooling mode. The display device according to any one of claims 1 to 3. The display device is installed so that the screen of the display module is parallel to the vertical direction at the time of use.
The display device according to any one of claims 1 to 4, wherein the second opening is provided above the power source in the first space. The display device is installed so that the screen of the display module is parallel to the vertical direction at the time of use.
The partition plate is provided so as to be parallel to the back surface of the display module.
Claims 1 to 1, wherein the first fan is provided so that the center of rotation of the first fan is at the same position as or above the power supply when viewed from the back side of the display module. The display device according to any one of claims 5. The suction amount of the first opening is smaller than the discharge amount of the second opening, and the sum of the maximum suction amount of the first opening and the maximum suction amount of the second opening is the maximum discharge amount of the third opening. Any of claims 1 to 6, wherein the opening area of the first opening and the second opening, and the opening area of the third opening and the flow rate of the first fan are set so as to be smaller than the above. The display device according to item 1. The display module includes a backlight having a light source substrate on which a plurality of LEDs are mounted, and a liquid crystal panel located on the front side of the backlight and displaying an image by modulating the light emitted from the backlight. It is a liquid crystal display module that has
The display device according to any one of claims 1 to 7, wherein the display device is characterized by the above. On the back side of the first partition plate, a second partition plate that divides the first space into a first sub space including the control board and a second sub space for taking in air for flowing into the second space is provided. Further prepare
A first relay opening for connecting the first subspace and the second subspace is provided at a position of the second partition plate facing the first fan.
The first opening is provided in the first subspace.
The second opening is provided in the second subspace.
The display device according to any one of claims 1 to 8, wherein the display device is characterized by the above. A second fan different from the first fan, which is provided at a position not facing the first relay opening of the first partition plate, is further provided.
The exterior member is
A fourth opening connecting the second subspace and the outside of the exterior member,
It has a fifth opening that connects the second space and the outside of the exterior member.
When the second fan is rotating, the air outside the exterior member that has flowed in from the fourth opening is discharged from the fifth opening via the second fan. Item 9. The display device according to item 9. The first temperature sensor that detects the temperature of the display module and
It has a second temperature sensor that detects the temperature of the outside air sucked in from the fourth opening.
The display device according to claim 10, wherein the control board controls the rotation speeds of the first fan and the second fan based on the detection values of the first temperature sensor and the second temperature sensor. .. A third partition plate that divides the first subspace into a first small space and a second small space is further provided.
A second relay opening is provided at the bottom of the third partition plate.
Any of claims 10 to 11, wherein the exterior member has a sixth opening connecting the first small space and the outside of the exterior member on the back side of the second relay opening. The image display device according to item 1. The first opening is provided on the bottom surface of the first subspace.
The display device according to claim 12, wherein a part of the air flowing into the first subspace from the first opening is exhausted from the sixth opening. A third fan that sucks in outside air is attached to the inside of the first opening.
The display device according to any one of claims 1 to 13, wherein the display device is characterized by the above. It has a plurality of the first fans corresponding to a plurality of display areas in which the screen of the display module is divided.
The control board according to any one of claims 1 to 14, wherein the control board controls the rotation speed of each first fan according to the brightness level of the image displayed in each display area. Display device. The control board is
The first fan corresponding to the display area whose brightness level is equal to or less than a predetermined threshold value is controlled to operate at a rotation speed equal to or less than the predetermined rotation speed.
The fifteenth aspect of the present invention is characterized in that the first fan corresponding to the display area whose brightness level is equal to or higher than the predetermined threshold value is controlled to operate at a rotation speed higher than the predetermined rotation speed. Display device. The control board is
When the display module is in a high-luminance display mode for displaying the image with a brightness higher than a predetermined brightness, the first fan is operated in the first cooling mode, and when not, the first fan is operated. The display device according to any one of claims 1 to 16, wherein the first fan is operated in the cooling mode of 2. The display device according to claim 17, wherein the high-luminance display mode is an HDR display mode for displaying an image having a high dynamic range. The display device according to any one of claims 1 to 18, wherein the control board does not rotate the first fan in the second cooling mode.

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