JP2013140278A - Self-luminous image display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a plasma display device capable of reducing the occurrence of noise in association with rotation of a cooling fan.SOLUTION: A device includes a self-luminous display panel 6, a cooling fan 9 for cooling the display panel 6, cooling fan control means 8 for controlling rotation drive of the cooling fan 9, and average luminance level acquisition means 7 for calculating the average luminance level of the display panel 6. The cooling fan control means 8 changes the rotation speed of the cooling fan 9 depending on the average luminance level value calculated by the average luminance level acquisition means 7.

Description

  The present invention relates to an image display device such as a plasma display device, and more particularly to a self-luminous image display device that cools a self-luminous display panel with a cooling unit.

  In recent years, a plasma display device, which is a self-luminous image display device of this type, has been developed to reduce heat generated from a display panel or the like only by cooling by natural convection in a casing due to thinning of the device and high-density mounting of components. Cannot be released sufficiently. Therefore, as a conventional technique for solving this problem, there is one described in Patent Document 1 below. In the prior art described in Patent Document 1, heat in a casing generated by a peripheral circuit such as a power supply circuit or a PDP (plasma display panel) is released to the outside of the casing using a cooling fan.

JP 2010-91715 A

  In the prior art described in Patent Document 1 above, the heat generated in the peripheral circuit such as the power supply circuit and the PDP is exhausted by the cooling fan. No consideration is given to the problem of noise such as sound.

  The present invention has been made from the above-described prior art, and an object of the present invention is to provide a self-luminous image display device that can reduce noise caused by cooling means.

  In order to solve the above problems, the present invention provides a self-luminous display panel, cooling means for cooling the display panel, control means for controlling driving of the cooling means, and one of the display panels. Average brightness level acquisition means for calculating an average brightness level value that is an average brightness per frame, and the control means is configured to change the cooling means according to the average brightness level value calculated by the average brightness level acquisition means. It is characterized by changing the cooling efficiency.

  According to the present invention configured as described above, the amount of generated heat changes according to the increase or decrease of the average luminance level value accompanying the light emission of the self-luminous display panel. Therefore, according to the average brightness level value of the display panel calculated by the average brightness level acquisition means, the cooling efficiency of the cooling means is changed by the control means, and the cooling means is used when the average brightness level value is low and the heat generation amount is small. Reduce the cooling efficiency. As a result, noise generated from the cooling means can be reduced.

  In the above configuration, when the average luminance level value calculated by the average luminance level acquisition unit is larger than a predetermined value, the control unit increases the cooling efficiency of the cooling unit, and the average luminance level value is When the value is smaller than the predetermined value, the cooling efficiency of the cooling means is lowered.

  With this configuration, the cooling efficiency of the cooling unit is increased when the average luminance level value is larger than the predetermined value, and the cooling efficiency of the cooling unit is decreased when the average luminance level value is smaller than the predetermined value. As a result, the cooling means can be controlled in two steps in accordance with the average luminance level value of the display panel caused by the heat generation amount, and therefore noise generated from the cooling means can be reduced by relatively simple control by the control means. .

  Further, in the above configuration, a housing for housing the display panel is provided, and the predetermined value is a value that prevents a temperature inside the housing from exceeding a predetermined temperature.

  With this configuration, when the average luminance level value is larger than a predetermined value, the cooling efficiency of the cooling unit is increased, so that the temperature inside the housing in which the display panel is accommodated can be prevented from exceeding the predetermined temperature.

  Further, in the above configuration, a screen brightness setting means for setting the screen brightness of the display panel, and a screen brightness setting value table based on a screen brightness setting value determined by the screen brightness setting means, the control means includes: The cooling efficiency of the cooling means is changed according to the screen brightness setting value table and the average brightness level value.

  With this configuration, the control unit cools according to the screen luminance setting value table based on the screen luminance setting value determined by the screen luminance setting unit and the average luminance level value calculated by the average luminance level acquisition unit. Change the cooling efficiency of the means. For this reason, since the cooling efficiency of the cooling means can be changed more accurately in correspondence with the amount of heat generated from the display panel, the noise generated from the cooling means can be more reliably reduced.

  In the above configuration, the screen brightness setting value table is a table proportional to the screen brightness setting value.

  With this configuration, by using a screen brightness setting value table that is proportional to the screen brightness setting value, the cooling efficiency of the cooling means by the control means is set in accordance with the screen brightness of the display panel set by the screen brightness setting means. Change can be controlled. Therefore, the cooling efficiency of the cooling means can be changed more accurately, and noise generated from the cooling means can be reduced more reliably.

  In the above configuration, the cooling means is a cooling fan, and the control means controls the rotational speed of the cooling fan.

  If comprised in this way, if a rotational speed is made high, a cooling fan will become high in cooling efficiency and a noise will become large, and if a rotational speed is made low, a cooling efficiency will become low and a noise will become small. Therefore, noise generated from the cooling fan can be reduced by controlling the rotation speed of the cooling fan by the control unit in accordance with the average luminance level value calculated by the average luminance level acquisition unit.

  According to the present invention, the cooling efficiency of the cooling means is changed according to the average brightness level value of the display panel, and the cooling efficiency of the cooling means is lowered when the average brightness level value is low and the heat generation amount is small. Noise generated from the cooling means can be reduced.

1 is a schematic configuration diagram illustrating a plasma display device according to a first embodiment of the present invention. 4 is a graph showing a rotation speed of a cooling fan with respect to an average luminance level value of the plasma display device. 4 is a flowchart illustrating control of a cooling fan after acquisition of an average luminance level value of the plasma display device. It is a flowchart which shows control of the cooling fan in step S602 of the said plasma display apparatus. 3 is a graph showing a noise level with respect to a rotation speed of a cooling fan of the plasma display device. It is a schematic block diagram which shows the plasma display apparatus which concerns on 2nd Embodiment of this invention. It is a graph which shows the rotational speed of the cooling fan with respect to the average luminance level value and screen luminance setting table value of the said plasma display apparatus. It is a graph which shows the temperature in the housing | casing with time passage of the conventional plasma display apparatus.

<First Embodiment>
Hereinafter, a self-luminous image display device according to the present invention will be described with reference to the drawings. FIG. 1 is a schematic configuration diagram illustrating a plasma display apparatus according to a first embodiment of the present invention, and FIG. 2 is a graph illustrating a rotation speed of a cooling fan with respect to an average luminance level value of the plasma display apparatus.

  The plasma display device 10 according to the first embodiment of the present invention is a so-called self-luminous image display device, and includes a housing 11 as shown in FIG. 1 is attached. The input terminal 1 is for inputting a video signal, and a video signal processing means 2 is connected to the input terminal 1. The video signal processing means 2 performs image processing optimal for display such as high image quality, and the panel display control means 5 to which the output of the video signal processing means 2 is input is input to the video signal processing means 2. Is connected.

  The panel display control means 5 is connected to the display panel 6, and the output of the panel display control means 5 is input to the display panel 6. Specifically, the panel display control means 5 performs control for causing the display panel 2 to display an image input to the panel display control means 5. Here, the display panel 6 is a self-luminous type PDP in which a plurality of pixels (not shown) constituted by self-luminous elements are attached in a matrix, and is controlled according to the control of the panel display control means 5. To display the video. Further, the display panel 6 is configured to increase or decrease the amount of heat generated from the display panel 6 in accordance with the increase or decrease of the average luminance level value accompanying the light emission of each pixel of the display panel 6.

  The video signal processing unit 2 is connected to an average luminance level acquisition unit 7, and an output of the video signal processing unit 2 is input to the average luminance level acquisition unit 7. The average luminance level acquisition unit 7 calculates an average luminance level value by calculating an average luminance level value of each pixel in one frame in the video signal to be displayed from the video signal after the image processing is performed by the video signal processing unit 2. Get as a level value. In other words, the average luminance level acquisition unit 7 is configured to acquire a sampling value of the average luminance level, that is, an input value (S) from the video signal processing unit 2 at regular intervals.

  Further, a cooling fan control unit 8 is connected to the average luminance level acquisition unit 7, and an output of the average luminance level acquisition unit 7 is input to the cooling fan control unit 8. Then, the cooling fan control means 8 is adapted to the cooling efficiency of the cooling fan 9 as the cooling means connected to the cooling fan control means 8 according to the average brightness level value acquired by the average brightness level acquisition means 7, specifically, Specifically, the rotation speed is controlled.

  The cooling fan 9 is configured such that the rotation speed can be controlled by changing the voltage applied to the cooling fan 9. Further, the cooling fan 9 is configured such that when the rotational speed is increased, the noise generated along with the rotation increases, and when the rotational speed is decreased, the noise generated along with the rotation decreases.

  Then, as shown in FIG. 2, the cooling fan control means 8 sets the rotational speed of the cooling fan 9 in two stages, a high speed that is a conventional fixed rotational speed and a low speed that is lower than this rotational speed. It is set as the structure controlled by. Specifically, the cooling fan control means 8 determines that the temperature in the housing 11 is high when the average brightness level value of the display panel 6 acquired by the average brightness continuous level acquisition means 7 is larger than a predetermined value A. Thus, the rotation speed of the cooling fan 9 is increased. Further, the cooling fan control means 8 determines that the temperature in the housing 11 is low when the average luminance level value acquired by the average luminance continuous level acquisition means 7 is smaller than the predetermined value A, and the cooling fan 9 Reduce the rotation speed.

  Further, the cooling fan control means 8 checks the continuation of the rotation speed (S) corresponding to the input value (S) acquired by the average luminance level acquisition means 7, and this rotation speed (S) continues for a certain period. Only in this case, the rotational speed of the cooling fan 9 is changed. That is, the cooling fan control means 8 performs control so that the rotation speed of the cooling fan 9 is not frequently changed when a steep change in the average luminance level of the video continues. Therefore, the cooling fan control means 8 controls the rotation speed of the cooling fan 9 to be low, for example, when the rotation speed of the cooling fan 9 is high and the average brightness level value remains dark for a while. To do.

  Here, the relationship between the light emission of the display panel 6 and the temperature will be described. The display panel 6 generates heat with the light emission of each pixel formed in a matrix on the display panel 6. The amount of heat generated by the display panel 6 is proportional to the number of pixels emitting light and the light emission degree (luminance). In addition to the display panel 6, an electric circuit (not shown) on which the panel display control means 5 and the like are mounted, a power supply circuit (not shown) for supplying power, and the like generate heat. For this reason, the cooling fan control means 8 prevents the components constituting the plasma display device 10 from exceeding the predetermined allowable temperature, that is, the predetermined value A that prevents the temperature in the housing 11 from exceeding the predetermined allowable temperature. Is based on. The cooling fan control means 8 is configured to switch and control the rotation speed of the cooling fan 9 in two steps of high speed and low speed with the predetermined value A as a reference. The predetermined value A is set to a value that is assumed that the temperature in the casing 11 does not exceed the T limit value based on actual measurement data obtained by measuring the temperature in the casing 11 of the plasma display device 10. ing.

  Next, control of the cooling fan 9 of the plasma display apparatus 10 according to the first embodiment will be described.

  FIG. 3 is a flowchart showing the control of the cooling fan 9 after obtaining the average luminance level value of the plasma display device 10, and FIG. 4 is a flowchart showing the control of the cooling fan 9 in step S602 of the plasma display panel device 10.

  First, the control of the cooling fan 9 of this flow is started by turning on the power of the plasma display device 10.

  Next, since the display panel 6 has been used most recently and there is a possibility that the display panel 6 is maintaining a high temperature, the initial value of the rotation speed (S) is set to a high speed, and this rotation speed ( The initial value of the input value (S) that is the basis of S) is maximized (step S601).

  Thereafter, whether or not the average luminance level acquisition unit 7 continues to acquire the input value (S) corresponding to the same rotation speed after the stability check count of the average luminance level value, that is, the initial value of Cnt is set to 0 (zero). Is confirmed for the stability of the input value (step S602).

  Here, details of the confirmation of the stability of the input value in step S602 will be described with reference to FIG.

  First, the average luminance level acquisition means 7 acquires an input value (T1) (step S701), and the rotational speed (T1) corresponding to the acquired input value (T1) is compared with the rotational speed (S) (step S701). S702). At this time, if the rotational speed (T1) is equal to the rotational speed (S), Cnt is counted up (Cnt + 1), and the process returns to step S602.

  On the other hand, when the rotation speed (T1) is not equal to the rotation speed (S), the average luminance level acquisition means 7 acquires the next input value (T2) (step S704). Thereafter, the rotational speed (T2) corresponding to the acquired input value (T2) is compared with the rotational speed (S) (step S705), and when the rotational speed (T2) is equal to the rotational speed (S). The process proceeds to step S703.

  Here, these steps 704 and S705 continue counting because it is considered that the rotational speed (T1) is deviated only once within the same continuous rotational speed.

  Furthermore, when the rotational speed (T2) is not equal to the rotational speed (S) in step S705, it is considered that the value has changed twice continuously from the rotational speed (S), and Cnt is reset to 0 (zero). (Step S706). Thereafter, the input value (T1) is substituted for the input value (S) (step S707), and the process returns to step S602.

  After step S602, it is determined whether or not Cnt has reached the specified number of times (step S603). If it is determined in step S603 that Cnt has not reached the specified number of times, the process proceeds to step S602. Repeat the stability check of the input value (S).

  On the other hand, if Cnt has reached the specified number in the determination in step S603, the rotational speed (S) is compared with the current rotational speed (step S604). If the rotation speed (S) is equal to the current rotation speed in the comparison in step S604, the rotation speed of the cooling fan 9 is not changed and Cnt is reset to 0 (zero) (step). In step S605), the process returns to step S602, and the input value stability check is repeated.

  If the current rotation speed is low and the rotation speed (S) is high as a result of the comparison in step S604, the rotation speed of the cooling fan 9 is changed to the rotation speed (S), that is, high speed (step S606). Next, after resetting Cnt to 0 (zero) (step S607), the process returns to step S602 to repeat the input value stability check.

  Further, if the current rotation speed is high and the rotation speed (S) is low as a result of the comparison in step S604, it is determined whether or not Cnt + X has been reached (step S608). If the result of determination in step S608 is that Cnt has not reached the specified number of times + X, the process returns to step S602 to continue to check the stability of the input value.

  On the other hand, if the result of determination in step S608 is that Cnt has reached the specified number + X, the rotation speed of the cooling fan 9 is changed to the rotation speed (S), that is, the low speed (step S606). Next, after resetting Cnt to 0 (zero) (step S607), the process returns to step S602 to repeat the input value stability check.

  Here, if the current rotation speed of the cooling fan 9 is high, there is a high possibility that the temperature in the casing 11 is high. If the rotation speed of the cooling fan 9 is immediately changed to a low speed, May exceed the T limit. Therefore, a time until the rotational speed is changed to a low speed by adding X times to the specified number of times is secured.

  Furthermore, depending on the variation of the average luminance level value, there is a mode in which steps S602 and S603 are repeated, the process of changing the rotation speed of the cooling fan 9 is not performed, and the rotation speed of the cooling fan 9 is not changed. In this mode, when the state of rotational speed (S) ≠ rotational speed (T1) = rotational speed (T2) continues, that is, when the input value (S) exceeds the predetermined value A, the predetermined value A is This is a case where there are frequent images below.

  In this case, since the video exceeding the predetermined value A does not continue or the video below the predetermined value A does not continue, the temperature in the housing 11 rises without changing the rotation speed of the cooling fan 9. It doesn't pass too much and there is no problem. Further, by adjusting the sampling interval and the specified number of times, it is possible to mitigate falling into a mode in which steps S602 and S603 are repeated.

  Here, in general, in the conventional plasma display device, the rotational speed of the cooling fan 9 is not taken into consideration, and is always controlled at a constant rotational speed. As shown in FIG. 8, in the conventional plasma display device, after the power is turned on, the display panel 6 and the like generate heat, and the temperature (T) in the housing 11 rises as time elapses. The limit value of the temperature T in the housing 11, that is, the T limit value is a temperature limit value for guaranteeing the reliability of each component of the plasma display device.

  Further, in the conventional plasma display device, when the temperature (T) in the housing 11 is the highest, that is, when the average luminance level value is 100%, the rotation speed of the cooling fan 9 is set so as not to exceed the T limit value. Had decided. In this case, as shown in FIG. 8, when the average luminance level value is 34% or when the average luminance level value is 10%, the amount of heat generated is reduced due to a reduction in the power load on the display panel 6, so The temperature rise in the body 11 is smaller than that in the case where the average luminance level value is 100%.

  That is, even in the case of a video signal with a low average luminance level value of the display panel 6, if the cooling is equivalent to the case of the average luminance level value of 100%, the display panel 6 is used in a state where the temperature T in the housing 11 is lower than the T limit value. Will be doing. For example, when a plasma display device is used as a television device for receiving and displaying broadcast waves, there is almost no video having an average luminance level value of 100% in the received broadcast wave video signal. It is known that the value is about 34%. In other words, in the conventional plasma display device, the cooling fan 9 is rotated excessively in almost all states, and the excess of the cooling fan 9 generates noise based on the rotation of the cooling fan 9. Yes.

  Further, in the conventional plasma display device, as shown in FIG. 2, even if the average luminance level value changes and the temperature in the housing 11 rises and falls due to the amount of heat generated from the display panel 6, the cooling fan 9 rotates. The speed did not fluctuate and was constant at high speed. In the conventional plasma display device, as shown in FIG. 5, the cooling fan 9 is driven to rotate at a constant rotational speed, and the noise level generated by the rotation of the cooling fan 9 is high. It was.

  Accordingly, when the average brightness level value of the display panel 6 is large as in the plasma display device 10 of the first embodiment described above, the rotation speed of the cooling fan 9 is set to a high speed state, and the average brightness of the display panel 6 is set. When the state where the level value is small continues, the rotation speed of the cooling fan 9 is changed to a low speed state. As a result, noise such as wind noise generated by the rotation of the cooling fan 9 can be reduced. Further, even when the rotation speed of the cooling fan 9 is lowered, the rotation speed of the cooling fan 9 is controlled so as not to exceed the T limit value for guaranteeing the reliability of each component of the plasma display device 10. Thus, the reliability of each component of the plasma display device 10 can be ensured.

  Further, the rotation speed of the cooling fan 9 is controlled by the cooling fan control means 8 in two steps of high speed and low speed so that the temperature in the housing 11 does not exceed the T limit value which is a predetermined allowable temperature. For this reason, the inside of the housing 11 can be reliably cooled by the relatively simple control by the cooling fan control means 8 and noise generated from the cooling fan 9 can be reduced.

Second Embodiment
Next, a second embodiment of the plasma display device according to the present invention will be described with reference to FIG.

  FIG. 6 is a schematic configuration diagram showing a plasma display device according to the second embodiment of the present invention, and FIG. 7 is a graph showing the rotation speed of the cooling fan with respect to the average brightness level value and the screen brightness setting table value of the plasma display device. In addition, about the same structure as 1st Embodiment among 2nd Embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  Specifically, the plasma display device 20 of the second embodiment includes a screen luminance setting means 3 for setting the screen luminance of the display panel 6 in addition to the configuration of the plasma display device 10 of the first embodiment, and the screen. And a screen brightness setting value table 4 to which screen brightness setting values output from the brightness setting means 3 are input. In the screen brightness setting value table 4, the output of the screen brightness setting value table 4 is connected to the input of the panel display control means 5 and the input of the cooling fan control means 8.

  The screen brightness setting means 3 allows a user to select a video mode as a screen setting mode from a menu screen according to the installation environment and video content in a commercially available thin television, and an adjustment value (for screen display for each video mode) The default value is set. This video mode includes standard standard mode (standard mode), super mode that is a high setting value, energy saving mode (sensor auto mode) that changes the setting value according to ambient brightness, and low setting value. There is a theater mode. Then, the screen brightness set by the screen brightness setting means 3 is changed for each video mode. In particular, the screen brightness setting value table 4 is determined by a peak brightness limit value that limits the peak brightness of the display panel 6 in the screen brightness of the display panel 6 of the plasma display device 20 regardless of the video mode. . In general, the peak luminance limit value can be adjusted individually in each video mode.

  The screen brightness setting value table 4 is a conversion table for converting the screen brightness setting value set by the screen brightness setting means 3 into an output value for use in internal calculations. That is, the screen brightness setting value table 4 is a conversion table proportional to the screen brightness setting value set by the screen brightness setting means 3. FIG. 7 shows the correspondence between the average luminance level value and the rotational speed of the cooling fan 9 with respect to the screen luminance setting table 7. In the range surrounded by the solid line in FIG. The left side is set to low speed, and the right side of the long broken line L is set to high speed.

  The long broken line L is determined from the temperature characteristics of the plasma display device 20, and is determined based on the measured data of the temperature in the casing 11 of the plasma display device 20. Further, the long broken line L is a straight line extending in the negative inclination direction from a point of 34% which is a video luminance level of a general broadcast wave when the screen luminance setting value is 0 (zero). Note that the inclination of the long broken line L is determined based on actually measured data of the temperature in the housing 11.

  As described above, in the plasma display device 20 of the second embodiment, the average brightness level value for switching the rotation speed of the cooling fan 9 to low speed or high speed is changed in the screen brightness setting value table 4 based on the screen brightness setting value. . Therefore, the difference from the plasma display device 10 of the first embodiment described above is that the value acquired from the screen brightness setting value table 4 is taken into account when the rotation speed (S) is obtained from the input value (S). .

  Here, in the conventional plasma display apparatus, the cooling fan 9 is rotated at high speed in the entire range surrounded by the solid line in FIG. Therefore, the plasma display device 20 of the second embodiment is configured as described above. As a result, for example, when the state where the average brightness level value is large and then the state where the average brightness level value is small continues, the cooling fan control means 8 rotates the cooling fan 9 as shown in FIGS. By controlling the speed, the rotational speed of the cooling fan 9 can be changed from high speed to low speed. Therefore, also in the plasma display apparatus 20 of the second embodiment, similarly to the plasma display apparatus 10 of the first embodiment, the rotation speed of the cooling fan 9 that has been rotated at a high speed in a state where the average luminance level value is small is reduced. Can be.

  Therefore, similarly to the plasma display device 10 of the first embodiment, when the average luminance level value of the video is small, heat generated from the display panel 6 is reduced. Therefore, this cooling is achieved by reducing the excessive rotation speed of the cooling fan 9 according to the average luminance level value of the display panel 6 within a range not exceeding the temperature for guaranteeing the reliability of each component of the plasma display device 20. Noise generated by the rotation of the fan 9 can be reduced. Further, in the second embodiment, when the rotation speed (S) is obtained from the input value (S), the value acquired from the screen brightness setting value table 4 is taken into consideration, and the screen brightness setting value parameter is used. doing. Therefore, since the accuracy of the temperature estimation of the display panel 6 can be improved, the noise generated by the rotation of the cooling fan 9 can be reduced more accurately and reliably.

  That is, for example, the amount of heat generated by the display panel 6 when a video having a predetermined equal average luminance level value is displayed is constant. In the case of the first embodiment, the screen luminance setting means 3 lowers the screen luminance. Even when the heat generation amount of the display panel 6 decreases, the rotational speed of the cooling fan 9 does not change. On the other hand, in the case of the second embodiment, when the screen brightness is lowered by the screen brightness setting means 3 and the heat generation amount of the display panel 6 is reduced, the rotation speed of the cooling fan 9 is controlled to be low. The rotational speed of the cooling fan 9 can be controlled accurately by the screen brightness of the panel 6, that is, the amount of heat generated from the display panel 6. Therefore, the rotational speed of the cooling fan 9 can be suppressed as compared with the conventional plasma display device, and the noise generated by the rotation of the cooling fan 9 can be more reliably reduced.

<Others>
In addition, each said embodiment is only what showed the specific example for implementing this invention, and the technical scope of this invention is not interpreted limitedly by these embodiment.

  That is, in each of the embodiments described above, the case of the plasma display devices 10 and 20 has been described. However, various self-luminous image display devices such as an EL display device using an organic EL (electroluminescence) element that emits light spontaneously, for example. If it is, there can exist an effect similar to said each embodiment.

  Furthermore, the configuration in which the cooling fan control means 8 adjusts the rotational speed of the cooling fan 9 in two stages, high speed and low speed, has been described. However, the rotational speed of the cooling fan 9 can be controlled in multiple stages, or the display panel 6 The rotational speed of the cooling fan 9 can be adjusted stepwise in correspondence with the average brightness level value.

  In addition, the cooling fan is used to dissipate the heat in the casing 11. However, even with a cooling means other than the cooling fan 9, noise increases when the cooling efficiency is increased, and noise decreases when the cooling efficiency is decreased. If it becomes small, any cooling means may be used.

DESCRIPTION OF SYMBOLS 1 Input terminal 2 Video signal processing means 3 Screen brightness setting means 4 Screen brightness setting value table 5 Panel display control means 6 Display panel 7 Average brightness level acquisition means 8 Cooling fan control means (control means)
9 Cooling fan (cooling means)
10,20 Plasma display device (Self-luminous image display device)
11 Housing A Predetermined value L Long dashed line

Claims (6)

A self-luminous display panel;
Cooling means for cooling the display panel;
Control means for controlling the driving of the cooling means;
Average luminance level acquisition means for calculating an average luminance level value that is an average luminance per frame of the display panel;
The control means changes the cooling efficiency of the cooling means in accordance with the average luminance level value calculated by the average luminance level acquisition means. The self-luminous image display device according to claim 1,
The control means increases the cooling efficiency of the cooling means when the average brightness level value calculated by the average brightness level acquisition means is greater than a predetermined value, and when the average brightness level value is less than the predetermined value. A self-luminous image display device characterized by lowering the cooling efficiency of the cooling means. The self-luminous image display device according to claim 2,
A housing for accommodating the display panel;
The self-luminous image display device, wherein the predetermined value is a value that prevents a temperature in the casing from exceeding a predetermined temperature. The self-luminous image display device according to claim 1,
Screen brightness setting means for setting the screen brightness of the display panel;
A screen brightness setting value table based on the screen brightness setting value determined by the screen brightness setting means,
The control means changes the cooling efficiency of the cooling means in accordance with the screen brightness setting value table and the average brightness level value. The self-luminous image display device according to claim 4,
The screen luminance set value table is a table proportional to the screen luminance set value. The self-luminous image display device according to any one of claims 1 to 5,
The cooling means is a cooling fan,
The self-luminous image display device, wherein the control means controls a rotation speed of the cooling fan.

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