JP2005241806A - Display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device which allows sufficient temperature control and does not deteriorate image quality to be displayed. <P>SOLUTION: The display device is provided with a plurality of display devices 1 to be numerously arranged, a cabinet 2 which supports the plurality of display devices, a heater 8 for heating which heats the display devices 1, a fan 6 for cooling which cools the display devices 1, a plurality of temperature sensors 3 which measure temperature of the display devices 1 and a control part 7 which collects and calculates output values from the temperature sensors 3. Then, the control part 7 controls the heater 8 for heating and the fan 6 for cooling based on a calculation result and changes drive conditions of the display devices 1 based on the calculation result. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a display device, and particularly relates to a large display device configured by arranging a large number of display devices.

  A large display device that is attached outdoors or on a wall surface is configured by arranging a large number of display devices in a matrix. Each display device is provided with a circuit for controlling an image to be displayed.

  In the display device, the display devices are arranged as close as possible so that the joints between the arranged display devices do not stand out in a tile shape. An image displayed on each display device is a part, and the entire display device in which the display devices are combined constitutes one image.

  Regarding the individual display devices constituting the display device, a monochromatic CRT (Cathode Ray Tube) is first put into practical use. A large number of single-color CRTs are arranged in a matrix to provide a display device. Thereafter, the display device having a plurality of pixels was developed by applying the principles of CRT and discharge tube, and the resolution of the display device was drastically improved.

  Furthermore, a liquid crystal display device is adopted as a display device, and a display device in which a large number of liquid crystal display devices are arranged in a matrix has been put to practical use. In addition, a display device employing a plasma display panel (PDP) or a fluorescent display tube (VFD) as a display device has been developed, and a wide variety of display devices can be used for the display device.

  Recently, a display device in which a large number of LEDs (Light Emitting Diodes) are arranged has also been developed. Large-sized display devices are used in an increasingly diverse range of applications, such as indoor high-resolution applications, outdoor ultra-high brightness applications, and light and thin building wall applications. It became possible to be used for.

  When the display device is used outdoors, the display device is required to have high luminance and high contrast. In order to satisfy this requirement, a setting such as applying a high voltage is required for the display device constituting the display device. Therefore, the amount of heat generated from the display device is increased as compared with the indoor display device, and the temperature inside the device of the high-brightness and high-contrast display device is increased.

  In addition, when the display device is used outdoors, sunlight may directly illuminate the display device, which increases the temperature inside the display device. Furthermore, when sunlight illuminates a part of the display device, a temperature difference occurs in the display device.

  An excessive temperature rise of the display device may change the characteristics of the display device and degrade the displayed image quality. Moreover, the excessive temperature rise of the display device may shorten the lifetime of the display device itself or the electronic components used in the display device.

  Therefore, in order to avoid an excessive temperature rise of the display device, a cooling fan is provided inside the display device. This cooling fan suppresses the temperature rise inside the display device.

  On the other hand, when the display device is used outdoors in a cold region, the display device must operate at a low temperature, and the characteristics of the display device may change to deteriorate the displayed image quality. For this reason, the display device is provided with a heater, and the temperature inside the display device is increased to control the temperature. Temperature control is particularly important in a display device that employs a display device such as a liquid crystal display element in which display characteristics are likely to change greatly with temperature.

  The temperature control of the display device is generally performed based on an output value of the temperature sensor provided inside. For example, in Patent Documents 1 to 3, at least one temperature sensor is provided inside the display device, and the cooling fan and heater are controlled based on the output value of the temperature sensor to equalize the temperature inside the display device. ing.

  In Patent Document 4, an intake port is provided in the lower part of the display device body and an exhaust port is provided in the upper part to control the temperature rise inside the display device.

JP-A-6-110563 JP-A-8-328489 JP-A-10-240139 JP 2000-165076 A

  As described in the background art, the display device sometimes deteriorates the displayed image quality by changing the characteristics of the display device depending on the use environment. For example, when sunlight illuminates a part of the display device, the temperature of the display device rises locally, resulting in a non-uniform temperature difference within the display device. In addition, even when heating with a heater during cold weather, a non-uniform temperature difference occurs in the display device due to the position of the heater, the heat generation of electronic components, the flow of heated air, and the like. Due to the uneven temperature difference in the display device, the characteristics of the display device may change to deteriorate the displayed image quality.

  In Patent Document 1 to Patent Document 3, at least one temperature sensor is provided inside the display device, and a cooling fan or a heater is controlled based on the output value of the temperature sensor to equalize the temperature inside the display device. Yes. However, there is a problem that the temperature control capability is limited only by controlling the cooling fan or heater, and the change in the characteristics of the display device cannot be sufficiently dealt with.

  Further, as in Patent Document 4, even in a method of creating an air flow inside a display device by providing an intake port at the bottom of the display device body and an exhaust port at the top, the temperature control capability is limited, and the display device There was a problem that it was not possible to respond sufficiently to changes in the characteristics of For example, when sunlight directly illuminates the display surface of the display device, in the example of Patent Document 4, sufficient temperature control may not be performed.

  Furthermore, when there is a sudden change in the environmental temperature or when there is a non-uniform temperature difference in the display device, temperature control inside the display device becomes even more difficult. In particular, in the case of a display device that employs a display device such as a liquid crystal display element that easily changes its display characteristics greatly depending on the temperature, the color and brightness change when the temperature in the display device changes, resulting in deterioration of the displayed image quality. There was a problem that occurred.

  In addition, when multiple temperature sensors are provided in the display device to control uneven temperature differences in the display device, normal temperature control cannot be performed if an abnormality occurs in some temperature sensors. There was a problem that caused deterioration.

  Therefore, the present invention provides a display device configured by arranging a large number of display devices, and can perform sufficient temperature control even when environmental temperature changes or non-uniform temperature differences are multiplied. An object is to provide a display device that does not deteriorate. In particular, it is an object of the present invention to provide a display device that can perform sufficient temperature control and display a good image even for a display device that employs a display device whose display characteristics are likely to change greatly with temperature.

  It is another object of the present invention to provide a display device that can perform normal temperature control and does not deteriorate the displayed image quality even when an abnormality occurs in some temperature sensors.

  According to the present invention, there are provided a plurality of display devices arranged in a large number, a housing that supports the plurality of display devices, a heating unit that heats the display device, a cooling unit that cools the display device, and a display device A plurality of temperature sensors that measure temperature and a control unit that collects and calculates output values from the temperature sensors, the control unit controls the heating unit and the cooling unit based on the calculation results, Based on the result, the drive condition of the display device is changed.

  A display device according to the present invention includes a plurality of display devices arranged in a large number, a housing that supports the plurality of display devices, a heating unit that heats the display device, a cooling unit that cools the display device, and a display device A plurality of temperature sensors that measure the temperature of the sensor and a control unit that collects and calculates an output value from the temperature sensor, and the control unit controls the heating unit and the cooling unit based on the result of the calculation and calculates Because the display device drive conditions are changed based on the results of the above, the temperature inside the display device can be sufficiently controlled, the drive conditions are optimized according to the temperature difference, and there is no deterioration in image quality. There is an effect that a uniform image with little unevenness can be displayed.

(Embodiment 1)
FIG. 1A is a plan view of a display device according to this embodiment. In the display device shown in FIG. 1A, a large number of display devices 1 are arranged in a matrix of 6 rows × 5 columns (a total of 30). The display devices 1 arranged in a matrix are supported by a housing 2. In the present embodiment, a liquid crystal display device is used as the display device 1, but the present invention is not limited to this, and other types of display devices may be used.

  The display device 1 is provided with a circuit for controlling an image to be displayed (not shown). The display device 1 is provided with a temperature sensor 3 for each. In FIG. 1A, it is illustrated as being provided on the display surface of the display device 1, but this is for schematically representing the position of the temperature sensor 3 with respect to the display device 1. Is provided on the rear surface of the display device 1 (the surface on the inner side of the housing 2).

  In the present embodiment, the temperature sensor 3 is provided for each display device 1. However, the present invention is not limited to this, and the display device 1 is divided into a plurality of display device 1 units, and the temperature sensor 3 is provided for each group. It may be a configuration.

  Next, FIG. 1B is a cross-sectional view of the display device according to this embodiment. The cross section shown in FIG. 1B is a cross section obtained by cutting the display device in the column direction. In the display device shown in FIG. 1B, the display device 1 is supported on one side of the housing 2, the intake port 4 is provided on the lower side of the other side, and the exhaust port 5 is provided on the upper side. A cooling fan 6 is attached. Further, on the other side of the housing 2, a control unit 7 that collects and calculates a temperature that is an output value from the temperature sensor 3 is provided. A heater 8 is provided at the bottom of the housing 2. In addition, the arrow of FIG.1 (b) represents the flow of air.

  In the display device shown in FIG. 1B, the control unit 7 calculates the output value from the temperature sensor 3, and controls the cooling fan 6 and the heating heater 8 based on the calculation result to control the display device 1. The temperature is controlled. That is, if the calculation result is higher than the predetermined temperature, the cooling fan 6 is operated, and if the calculation result is lower than the predetermined temperature, the heater 8 is operated.

  Further, in the present embodiment, the control unit 7 changes the driving condition of the display device 1 based on the calculation result, and the display device 1 is driven in such a direction that a good display is obtained at the temperature of the calculation result. The conditions are close. That is, the drive conditions of the display device 1 are optimized based on the calculation result.

  In the present embodiment, the cooling fan 6 is used as the cooling means and the heating heater 8 is used as the heating means. However, the present invention is not limited to this, and cooling controlled based on the calculation result of the control unit 7. Other types may be used as long as the means and the heating means.

  Next, temperature control of the display device according to the present embodiment will be described based on a flowchart. FIG. 2 is a flowchart showing temperature control of the display device according to the present embodiment. When the display device is started, first, the control unit 7 instructs each temperature sensor 3 to collect the temperature of each display device 1 (step AS1). Each temperature sensor 3 that has received an instruction to collect the temperature measures the temperature of each display device 1 and sends the temperature to the control unit 7 as an output value. The control part 7 collects the temperature of each display device 1 by collecting the output value from each temperature sensor 3 (step AS2).

  The control unit 7 obtains an average temperature (Tave) by calculation from the collected temperatures of the display devices 1 (step AS3). Then, the control unit 7 compares the obtained average temperature (Tave) with the set temperature on the high temperature side (+ 40 ° C. in the present embodiment) (step AS4). As a result of the comparison, when the average temperature (Tave) is higher than the set temperature on the high temperature side (Tave> + 40 ° C.), the control unit 7 turns on the cooling fan 6 (step AS5). On the other hand, when the average temperature (Tave) is equal to or lower than the set temperature on the high temperature side (Tave ≦ + 40 ° C.), the control unit 7 turns off the cooling fan 6 (step AS6).

  Further, the control unit 7 compares the obtained average temperature (Tave) with the set temperature on the low temperature side (+ 10 ° C. in the present embodiment) (step AS7). As a result of the comparison, when the average temperature (Tave) is lower than the set temperature on the low temperature side (Tave <+ 10 ° C.), the control unit 7 turns on the heater 8 (step AS8). On the other hand, when the average temperature (Tave) is equal to or higher than the set temperature on the low temperature side (Tave ≧ + 10 ° C.), the control unit 7 turns off the heater 8 (step AS9).

  Here, the temperature control from step AS4 to step AS9 will be described specifically. First, when sunlight directly illuminates the display device 1, the temperature of the display device 1 may reach about 80 ° C. In this case, it is determined that the average temperature (Tave) is higher than the set temperature on the high temperature side, the control unit 7 turns on the cooling fan 6 (step AS5), and adjusts the temperature of the display device 1 to about 40-50 ° C. To do. When the temperature of the display device 1 falls to 40 ° C. or lower, the control unit 7 turns off the cooling fan 6 (step AS6).

  On the other hand, when used in a cold region of −20 ° C., it is determined that the average temperature (Tave) is lower than the set temperature on the low temperature side, the control unit 7 turns on the heater 8 (step AS8), and the display device 1 Is adjusted to about 0 to 10 ° C. When the temperature of the display device 1 rises to 10 ° C. or higher, the control unit 7 turns off the heater 8 (step AS9).

  The temperature of the display device 1 can be adjusted to about 0 to 50 ° C. by the temperature control from step AS4 to step AS9 as described above. However, it is difficult to obtain a high-quality image in a display device such as a liquid crystal display element whose display characteristics are likely to change greatly with temperature only by temperature control from step AS4 to step AS9. Therefore, in the display device according to the present embodiment, an optimum driving condition is set at each temperature of the display device 1, and the display device 1 is driven under this driving condition, so that a high-quality image can be displayed.

  If it demonstrates with the flowchart of FIG. 2, the control part 7 will set the optimal drive condition based on average temperature (Tave) (step AS10). The circuit of the display device 1 drives the display device 1 based on the set drive condition (step AS11). By driving the display device 1 based on the set driving conditions, a high-quality display can be obtained (step AS12). After the display (step AS12), the control unit 7 instructs the temperature sensor 3 to collect the temperature again (step AS1).

  Here, the display characteristics of the liquid crystal display element employed in the display device 1 are likely to change greatly depending on the temperature. More specifically, the liquid crystal display element is a display device that displays an image by changing the polarization characteristics of transmitted light by applying a voltage to the liquid crystal. Here, the viscosity of the liquid crystal changes depending on the temperature. That is, the viscosity increases at a low temperature, and the viscosity decreases at a high temperature. The display characteristics change greatly due to the change in the viscosity of the liquid crystal.

  Therefore, in step AS10, optimal driving conditions for the display device 1 are set in accordance with the change in the viscosity of the liquid crystal. That is, since the viscosity of the liquid crystal increases at a low temperature, the voltage value (V) of the drive pulse applied to the liquid crystal or the width (Tw) of the drive pulse is set larger than that at the normal temperature. Further, since the viscosity of the liquid crystal decreases at a high temperature, the voltage value (V) of the drive pulse applied to the liquid crystal or the width (Tw) of the drive pulse is set smaller than that at the normal temperature.

  Note that by performing temperature control that is stricter than the temperature control from step AS4 to step AS9, it may be considered that the optimization of the drive conditions as in step AS10 is unnecessary. However, in order to perform temperature control that is stricter than the temperature control from step AS4 to step AS9 described above, it is necessary to mount a powerful heating / cooling means on the display device, which causes an increase in cost and power consumption. Not right.

  The setting of the driving condition described above (step AS10) will be specifically described based on a flowchart. FIG. 3 is a flowchart showing the temperature control of the display device according to the present embodiment, in which the drive condition setting part is described in detail. The same operations as those in the flowchart shown in FIG. 2 will be described with the same reference numerals.

  When the display device is started, first, the control unit 7 instructs each temperature sensor 3 to collect the temperature of each display device 1 (step AS1), and collects the temperature of each display device 1 (step AS2). . Next, in the control part 7, average temperature (Tave) is calculated | required by calculation from the temperature of each collected display device 1 (step AS3).

  The control unit 7 compares the average temperature (Tave) with the set temperature on the high temperature side (+ 40 ° C. in the present embodiment) (step AS4), and the average temperature (Tave) is higher than the set temperature on the high temperature side. At (Tave> + 40 ° C.), the controller 7 turns on the cooling fan 6 (step AS5). Further, in the follow chart of FIG. 3, the control unit 7 compares the average temperature (Tave) with the second high temperature side set temperature (+ 45 ° C. in the present embodiment) (step BS1). As a result of the comparison, when the average temperature (Tave) is higher than the set temperature on the second high temperature side (Tave> + 45 ° C.), the control unit 7 sets the drive condition at high temperature (step BS2).

  On the other hand, when the average temperature (Tave) is equal to or lower than the set temperature on the second high temperature side (Tave ≦ + 45 ° C.), the control unit 7 sets the drive condition at normal temperature (step BS3). Here, when the liquid crystal display element is employed in the display device 1, assuming that the drive pulse voltage value is V1 and the drive pulse width is Tw1, the drive condition at high temperature is a drive smaller than V1. The drive voltage width Tw2 is smaller than the pulse voltage value V2 and Tw1.

  Note that the driving condition at high temperature is not limited to the case where both the voltage value of the driving pulse and the width of the driving pulse are set to be smaller than the driving condition at the normal temperature, either the driving pulse voltage value or the driving pulse width. Only one of the parameters may be made smaller than the driving condition at normal temperature.

  When the average temperature (Tave) is equal to or lower than the set temperature on the high temperature side (Tave ≦ + 40 ° C.) in the temperature determination in step AS4, the control unit 7 turns off the cooling fan 6 (step AS6). Next, the control unit 7 compares the average temperature (Tave) with the set temperature on the low temperature side (+ 10 ° C. in the present embodiment) (step AS7), and the average temperature (Tave) is lower than the set temperature on the low temperature side. In the case (Tave <+ 10 ° C.), the controller 7 turns on the heater 8 (step AS8).

  Further, in the follow chart of FIG. 3, the control unit 7 compares the average temperature (Tave) with the second low temperature side set temperature (+ 5 ° C. in the present embodiment) (step BS4). As a result of the comparison, when the average temperature (Tave) is lower than the set temperature on the second low temperature side (Tave <+ 5 ° C.), the control unit 7 sets the driving condition at the low temperature (step BS5).

  On the other hand, when the average temperature (Tave) is equal to or higher than the set temperature on the second low temperature side (Tave ≧ + 5 ° C.), the control unit 7 sets the drive condition at normal temperature (step BS3). Here, the driving condition at low temperature is V3 of the driving pulse voltage value larger than V1, and Tw3 of the driving pulse width larger than Tw1. Note that the driving condition at low temperature may be a case where only one parameter of the voltage value of the driving pulse or the width of the driving pulse is set larger than the driving condition at the normal temperature.

  When the average temperature (Tave) is equal to or higher than the set temperature on the low temperature side (Tave ≧ + 10 ° C.) in the temperature determination in step AS7, the control unit 7 turns off the heater 8 (step AS9). And the control part 7 sets the drive condition at the time of normal temperature (step BS3).

  Summarizing the setting of the above driving conditions, when the average temperature (Tave) is + 5 ° C. ≦ Tave ≦ + 45 ° C., the voltage value of the driving pulse is set to V1 and the width of the driving pulse is set to Tw1. When the average temperature (Tave) is Tave> + 45 ° C., the voltage value of the drive pulse is set to V2, and the width of the drive pulse is set to Tw2. When the average temperature (Tave) is Tave <+ 5 ° C., the voltage value of the drive pulse is set to V3, and the width of the drive pulse is set to Tw3. Here, the relationship between the voltage values of the drive pulses is V2 <V1 <V3, and the relationship between the widths of the drive pulses is Tw2 <Tw1 <Tw3.

  Next, the circuit of the display device 1 drives the display device 1 based on the driving conditions set in step BS2, step BS3, and step BS5 (step AS11). By driving the display device 1 based on the set driving conditions, high-quality display can be obtained in the entire practical temperature range (for example, 0 ° C. to 50 ° C.) (step AS12). After the display (step AS12), the control unit 7 instructs the temperature sensor 3 to collect the temperature again (step AS1).

  As described above, in the display device according to the present embodiment, the control unit 7 calculates the average value (Tave) of the output values from the plurality of temperature sensors 3, and obtains the average value (Tave) as a result of the calculation. Based on this, the driving conditions of the display device 1 are changed, so that sufficient temperature control can be performed in the entire practical temperature range (for example, 0 ° C. to 50 ° C.), and a good display that does not deteriorate the image quality is obtained. It is done.

(Embodiment 2)
In the first embodiment, the temperature measured by each temperature sensor 3 is collected in the control unit 7 and calculated by the control unit 7 to obtain an average temperature (Tave), and the drive condition is determined based on the average temperature (Tave). The temperature was controlled by setting.

  However, when the display device is operated at a high temperature, if the difference between the maximum temperature (Tmax) and the average temperature (Tave) is large, the driving condition is set based on the average temperature (Tave) and the display device is driven. The display device 1 in the vicinity of the maximum temperature (Tmax) cannot maintain the same image quality as the other display devices 1.

  Further, when the display device is operated at a low temperature, if the difference between the minimum temperature (Tmin) and the average temperature (Tave) is large, by setting the driving condition based on the average temperature (Tave) and driving the display device, The display device 1 in the vicinity of the minimum temperature (Tmin) cannot maintain the same image quality as the other display devices 1.

  Therefore, in this embodiment, when the display device is operated at a high temperature, that is, at a temperature at which the cooling means is used, the driving condition is set based on the maximum temperature (Tmax) instead of the average temperature (Tave). When the display device is operated at a low temperature, that is, at a temperature at which the heating means is used, the driving condition is set based on the minimum temperature (Tmin) instead of the average temperature (Tave).

  Hereinafter, temperature control of the display device according to the present embodiment will be specifically described based on a flowchart. FIG. 4 is a flowchart showing temperature control of the display device according to the present embodiment. In addition, the same code | symbol is attached | subjected and demonstrated about the part of the same operation | movement as the flowchart shown in FIG.2 and FIG.3.

  When the display device is started, first, the control unit 7 instructs each temperature sensor 3 to collect the temperature of each display device 1 (step AS1), and collects the temperature of each display device 1 (step AS2). . Next, in the control part 7, average temperature (Tave) is calculated | required by calculation from the temperature of each collected display device 1 (step AS3).

  The control unit 7 compares the average temperature (Tave) with the set temperature on the high temperature side (+ 40 ° C. in the present embodiment) (step AS4), and the average temperature (Tave) is higher than the set temperature on the high temperature side. At (Tave> + 40 ° C.), the controller 7 turns on the cooling fan 6 (step AS5). Further, in the follow chart of FIG. 4, the control unit 7 calculates the maximum temperature (Tmax) from the output values collected from each temperature sensor 3 (step CS1).

  Next, in the display device according to the present embodiment, instead of the average temperature (Tave), the maximum temperature (Tmax) is compared with the set temperature on the second high temperature side (+ 45 ° C. in the present embodiment) (step) CS2). As a result of the comparison, when the maximum temperature (Tmax) is higher than the set temperature on the second high temperature side (Tmax> + 45 ° C.), the control unit 7 sets the driving condition at high temperature (step BS2). On the other hand, when the maximum temperature (Tmax) is equal to or lower than the set temperature on the second high temperature side (Tmax ≦ + 45 ° C.), the control unit 7 sets the drive condition at room temperature (step BS3).

  When the average temperature (Tave) is equal to or lower than the set temperature on the high temperature side (Tave ≦ + 40 ° C.) in the temperature determination in step AS4, the control unit 7 turns off the cooling fan 6 (step AS6). Next, the control unit 7 compares the average temperature (Tave) with the set temperature on the low temperature side (+ 10 ° C. in the present embodiment) (step AS7), and the average temperature (Tave) is lower than the set temperature on the low temperature side. In the case (Tave <+ 10 ° C.), the controller 7 turns on the heater 8 (step AS8).

  Further, in the follow chart of FIG. 4, the control unit 7 calculates the minimum temperature (Tmin) from the output values collected from each temperature sensor 3 (step CS3). Then, the control unit 7 compares the lowest temperature (Tmin) with the second low temperature side set temperature (+ 5 ° C. in the present embodiment) instead of the average temperature (Tave) (step CS4). As a result of the comparison, when the minimum temperature (Tmin) is lower than the second low temperature side set temperature (Tmin <+ 5 ° C.), the control unit 7 sets the driving condition at the low temperature (step BS5). On the other hand, when the minimum temperature (Tmin) is equal to or higher than the set temperature on the second low temperature side (Tmin ≧ + 5 ° C.), the control unit 7 sets the drive condition at room temperature (step BS3).

  When the average temperature (Tave) is equal to or higher than the set temperature on the low temperature side (Tave ≧ + 10 ° C.) in the temperature determination in step AS7, the control unit 7 turns off the heater 8 (step AS9). And the control part 7 sets the drive condition at the time of normal temperature (step BS3).

  Summarizing the setting of the above driving conditions, when the average temperature (Tave) is in the range of + 10 ° C. or higher and + 40 ° C. or lower (+ 10 ° C. ≦ Tave ≦ + 40 ° C.), the cooling fan 6 and the heating heater 8 are in the OFF state. The voltage value of the drive pulse is set to V1, and the width of the drive pulse is set to Tw1. When the average temperature (Tave) is higher than + 40 ° C. and the maximum temperature (Tmax) is + 45 ° C. or lower (Tmax ≦ + 45 ° C.), the cooling fan 6 is in the ON state, the drive pulse voltage value is V1, The width is set to Tw1.

  When the average temperature (Tave) is lower than + 10 ° C. and the minimum temperature (Tmin) is + 5 ° C. or higher (Tmin ≧ + 5 ° C.), the heater 8 is ON and the voltage value of the drive pulse is V1 The width is set to Tw1. When the average temperature (Tave) is higher than + 40 ° C. and the maximum temperature (Tmax) is Tmax> + 45 ° C., the cooling fan 6 is in the ON state, the drive pulse voltage value is V2, and the drive pulse width is Tw2. Is set. When the average temperature (Tave) is lower than + 10 ° C. and the minimum temperature (Tmin) is Tmin <+ 5 ° C., the heater 8 is turned on, the drive pulse voltage value is V3, and the drive pulse width is Tw3. Is set.

  Next, the circuit of the display device 1 drives the display device 1 based on the driving conditions set in step BS2, step BS3, and step BS5 (step AS11). By driving the display device 1 based on the set drive conditions, a high-quality display can be obtained in the entire practical temperature range (step AS12). After the display (step AS12), the control unit 7 instructs the temperature sensor 3 to collect the temperature again (step AS1).

  As described above, in the display device according to the present embodiment, the control unit 7 calculates the maximum temperature (Tmax) or the minimum temperature (Tmin) of the output values from the plurality of temperature sensors 3, and the maximum as a result of the calculation. Since the driving conditions of the display device 1 are changed based on the temperature (Tmax) or the minimum temperature (Tmin), further sufficient temperature control is possible, and a good image can be obtained in the entire practical temperature range.

(Embodiment 3)
Whether the internal temperature of the display device rises due to sunlight or when the internal temperature of the display device rises due to the use of a heater in a cold region, the internal temperature of the display device rises uniformly. is not. Even when the temperature control is performed by the cooling fan, the internal temperature of the display device may vary. For example, in the display device shown in FIG. 1B, the cold air taken in from the intake port 4 controls the internal temperature of the display device by cooling the display device 1. The cold air taken in from the intake port 4 is warmed by cooling the display device 1, and a part thereof is discharged from the exhaust port 5. However, a part of the air heated by the display device 1 is not discharged from the exhaust port 5 but is accumulated on the upper part of the housing 2.

  The warmed air accumulates in the upper part of the housing 2, thereby causing a variation in the internal temperature of the display device, so that the upper part of the housing 2 is warm and the lower part is cold. FIG. 5A schematically shows the temperature distribution of the display device. In the display device shown in FIG. 5A, the upper part is in a high temperature region, and the state is changed to a low temperature region as it goes to the lower part. FIG. 5B shows a cross-sectional view of the display device shown in FIG. In the display device shown in FIG. 5B, a state in which heat is accumulated in the upper part of the housing 2 is schematically shown. In addition, the arrow of FIG.5 (b) represents the flow of air.

  Further, when used outdoors, there may be an environment where a part of the display device is illuminated with sunlight and the other part is shaded. In such an environment, the internal temperature of the display device is not uniform, and the temperature difference within the display device becomes large.

  As described above, the internal temperature of the display device is often difficult to control uniformly, and a large temperature difference may occur in the display device. When a large temperature difference occurs in the display device, when setting conditions for each display device based on the average temperature of the display device, there are also display devices that deviate from the optimum driving conditions. For this reason, there is a problem that display characteristics of each display device vary and the image quality of the display device deteriorates.

  Therefore, in the display device according to the present embodiment, the driving conditions of all display devices are not determined based on representative values such as the average temperature of the display device, but the driving conditions of each display device are individually determined based on each temperature sensor. decide.

  Hereinafter, temperature control of the display device according to the present embodiment will be specifically described based on a flowchart. FIG. 6 is a flowchart showing temperature control of the display device according to the present embodiment. Note that portions having the same operations as those in the flowchart shown in FIG.

  When the display device is started, first, the control unit 7 instructs each temperature sensor 3 to collect the temperature of each display device 1 (step AS1), and collects the temperature of each display device 1 (step AS2). . Next, in the control part 7, average temperature (Tave) is calculated | required by calculation from the temperature of each collected display device 1 (step AS3).

  The control unit 7 compares the average temperature (Tave) with the set temperature on the high temperature side (+ 40 ° C. in the present embodiment) (step AS4), and the average temperature (Tave) is higher than the set temperature on the high temperature side. At (Tave> + 40 ° C.), the controller 7 turns on the cooling fan 6 (step AS5). On the other hand, when the average temperature (Tave) is equal to or lower than the set temperature on the high temperature side (Tave ≦ + 40 ° C.), the control unit 7 turns off the cooling fan 6 (step AS6).

  Next, the control unit 7 compares the average temperature (Tave) with the set temperature on the low temperature side (+ 10 ° C. in the present embodiment) (step AS7), and the average temperature (Tave) is lower than the set temperature on the low temperature side. In the case (Tave <+ 10 ° C.), the controller 7 turns on the heater 8 (step AS8). On the other hand, when the average temperature (Tave) is equal to or higher than the set temperature on the low temperature side (Tave ≧ + 10 ° C.), the control unit 7 turns off the heater 8 (step AS9).

  Next, in the display device according to the present embodiment, the driving condition of each display device 1 is set based on the output value of each temperature sensor 3. The case where the temperature sensor 3 is provided corresponding to each display device 1 as shown in FIG. Note that the name of each display device 1 is P (n, m), and the name of the temperature sensor 3 corresponding to the name is S (n, m). n represents a row number, m represents a column number, P (1,1) represents the display device 1 in the first row and first column, and S (1,1) is provided in the display device 1 in the first row and first column. The obtained temperature sensor 3 is shown. In FIG. 1A, there are display devices P (1,1) to P (6,5).

  Based on the flowchart of FIG. 6, the setting of the driving conditions of each display device 1 will be described. First, the temperature of the display device 1 (P (1, 1)) is measured by the temperature sensor 3 (S (1, 1)) (step DS1). Based on the measured temperature, the control unit 7 sets an optimum driving condition for the display device 1 (P (1, 1)) (step DS1A).

  Next, the temperature of the display device 1 (P (1,2)) in the first row and the second column is measured by the temperature sensor 3 (S (1,2)) (step DS2). Based on the measured temperature, the control unit 7 sets an optimum driving condition for the display device 1 (P (1, 2)) (step DS2A).

  The drive conditions are similarly set for all the display devices 1, and the temperature of the last display device 1 (P (6, 5)) in the sixth row and the fifth column is set by the temperature sensor 3 (S (6, 5)). Is measured (step DS30). Based on the measured temperature, the control unit 7 sets an optimum driving condition for the display device 1 (P (6, 5)) (step DS30A).

  For example, when the temperature of a certain temperature sensor 3 (S (n, m)) is not lower than + 5 ° C. and not higher than + 45 ° C., the drive condition is set such that the voltage value of the drive pulse is V1 and the width of the drive pulse is Tw1. Is set. When the temperature of a certain temperature sensor 3 (S (n, m)) is higher than + 45 ° C., the voltage value of the drive pulse is set to V2, and the width of the drive pulse is set to Tw2. When the temperature of a certain temperature sensor 3 (S (n, m)) is lower than + 5 ° C., the voltage value of the drive pulse is set to V3 and the width of the drive pulse is set to Tw3. Here, the relationship between the voltage values of the drive pulses is V2 <V1 <V3, and the relationship between the widths of the drive pulses is Tw2 <Tw1 <Tw3.

  After setting the driving conditions for all the display devices 1, the circuit of the display device 1 drives the display devices 1 based on the set driving conditions (step AS11). By driving the display device 1 based on the set driving conditions, a high-quality display can be obtained even if the internal temperature is not uniform in the display device (step AS12). After the display (step AS12), the control unit 7 instructs the temperature sensor 3 to collect the temperature again (step AS1).

  As described above, in the display device according to the present embodiment, instead of changing the driving condition of the display device 1 based on the average temperature (Tave) that is the result of the calculation, the output from each temperature sensor 3 is output. Since the driving conditions of the display device 1 located in the vicinity of each temperature sensor 3 are changed based on the value (temperature), fine temperature control is possible, and the internal temperature of the display device is uneven. However, it is possible to obtain a high-quality image without display unevenness.

  In the present embodiment, the case where the temperature sensor 3 is provided for each display device 1 has been described. However, the present invention is not limited to this, and a plurality of display devices 1 are grouped into one group. A configuration in which one temperature sensor 3 is provided corresponding to the group may be used.

  Specifically, when the four display devices 1 are in one group and one temperature sensor 3 is provided for the group, the display device 1 is assigned to the group based on the temperature obtained by the one temperature sensor 3. The drive conditions of the four display devices 1 to which it belongs are optimized.

  Further, in the flowchart shown in FIG. 6, after the temperature of each temperature sensor 3 is measured in step AS2, the temperature of each temperature sensor 3 is further measured in step DS1 or the like. However, the present invention is not limited to this, and the temperature measurement in step DS1 or the like may be omitted, and the driving conditions of each display device 1 may be optimized in step DS1A or the like based on the temperature measured in step AS2.

  Further, in the present embodiment, a display device in which a large number of the display devices 1 shown in FIG. 1A are arranged in a matrix of 6 rows × 5 columns (a total of 30) has been described. The number of devices 1 is not limited.

(Embodiment 4)
When a plurality of temperature sensors are provided in the display device, there is a problem that normal temperature control cannot be performed due to failure of some of the temperature sensors. For example, when temperature control is performed based on the average temperature (Tave) of a plurality of temperature sensors as in the first embodiment, if some temperature sensors show an abnormal value due to a failure, the correct average temperature (Tave) is obtained. Cannot be controlled normally. Further, when temperature control is performed based on the maximum temperature (Tmax) or the minimum temperature (Tmin) in a plurality of temperature sensors as in the second embodiment, if some temperature sensors show an abnormal value due to a failure, The value is determined as the maximum temperature (Tmax) or the minimum temperature (Tmin), and normal temperature control cannot be performed.

  As described above, when some of the temperature sensors show an abnormal value due to a failure, normal temperature control cannot be performed, causing display unevenness and the like, resulting in a problem that image quality is deteriorated. Therefore, in the present embodiment, an abnormal value of the temperature sensor is detected, and an output value (temperature) from the temperature sensor where the abnormality is detected is corrected by a predetermined calculation.

  FIG. 7 is a plan view of the display device according to this embodiment. The correction of the abnormal value of the temperature sensor will be specifically described with reference to FIG. First, in the display device shown in FIG. 7, display devices 1 are arranged in a matrix of 6 rows and 5 columns, and each display device 1 is provided with a temperature sensor 3. Here, the temperature sensor 3 provided in the display device 1 in the nth row and the mth column is represented as S (n, m).

  In FIG. 7, when the temperature sensor 3 of S (5, 3) shows an abnormal value, an average value of the left and right temperature sensors 3S (5, 2) and S (5, 4) is obtained, and the average value is obtained. Presumed to be the temperature of S (5,3). Further, an average value of the upper and lower temperature sensors 3S (4, 3) and S (6, 3) is obtained, and the average value is estimated as S (5, 3), or the upper, lower, left and right temperature sensors 3S (4). , 3), S (6, 3), S (5, 2), S (5, 4) can be obtained, and the average can be estimated as S (5, 3).

  As described above, in the present embodiment, the average value of the temperature sensors 3S (n ± 1, m ± 1) adjacent to the temperature sensor 3S (n, m) indicating an abnormal value is calculated as the temperature sensor 3S (n, Correction for estimating the normal value of m) is performed.

  As another correction method, for example, when the temperature sensor 3 of S (3, 4) shows an abnormal value, the temperature sensor 3 of S (3, 2) located at a symmetrical position with respect to the center of the display device. Is estimated to be the temperature of the temperature sensor 3 at T (3, 4). This correction method utilizes the fact that the temperature distribution of the display device is symmetrical with respect to the center of the display device.

  The temperature control of the display device according to the present embodiment using the correction method as described above will be described based on a flowchart. FIG. 8 is a flowchart showing temperature control of the display device according to the present embodiment. Note that portions having the same operations as those in the flowchart shown in FIG.

  When the display device is started, first, the control unit 7 instructs each temperature sensor 3 to collect the temperature of each display device 1 (step AS1), and collects the temperature of each display device 1 (step AS2). . Next, an abnormality of each temperature sensor 3 is detected (step ES1). The abnormality detection in step ES1 detects that the temperature sensor 3 is abnormal when, for example, a temperature that deviates significantly from the data measured periodically is measured or when a protruding temperature is measured.

  The above-described correction is performed on the temperature sensor 3 determined to be abnormal in step ES1, and the normal value is estimated and corrected (step ES2). Next, the control part 7 calculates | requires average temperature (Tave) by calculation from the temperature of each display device 1 containing the corrected temperature (step AS3).

  The flowchart after obtaining the average temperature (Tave) is the same as the process from step AS4 to step AS12 shown in FIG.

  As described above, in the display device according to the present embodiment, the control unit 7 detects an abnormality of the temperature sensor 3 from the collected output value (temperature), and the output value (from the temperature sensor 3 where the abnormality is detected ( Temperature) is corrected by a predetermined calculation, so that appropriate temperature control can be performed based on the corrected temperature, and an image with high image quality can be obtained.

(Embodiment 5)
The internal temperature of the display device according to Embodiment 1 depends on the environmental temperature at which the display device is provided and the direct sunlight irradiation conditions. For example, in a situation where the ambient temperature exceeds 40 ° C. and direct sunlight is radiated, the cooling fan 6 provided in the display device according to the first embodiment has insufficient temperature control capability, and the display device May not be uniformly cooled.

  The display device according to Embodiment 1 has a structure as shown in FIG. In the display device shown in FIG. 1B, the air inlet 4 and the air outlet 5 are provided on a surface parallel to the surface on which the display device 1 is arranged. Therefore, the warmed air tends to accumulate on the upper portion of the display device, and heat is trapped on the upper portion of the display device. FIG. 5B schematically shows how heat is accumulated in the display device having the structure as shown in FIG. FIG. 5B shows that heat accumulates in the upper part of the housing 2 and cannot be exhausted by the cooling fan 6.

  In order to solve the above problems, in the display device according to the present embodiment, an intake port is provided on the bottom surface of the housing, and an exhaust port is provided on the top surface. FIG. 9A shows a plan view of the display device according to this embodiment, and FIG. 9B shows a cross-sectional view of the display device according to this embodiment. In the display device according to the present embodiment, an intake port 4 is provided on the bottom surface of the housing 2 and an exhaust port 5 is provided on the top surface. That is, the intake port 4 and the exhaust port 5 are provided at right angles to the surface on which the display device 1 is arranged, and a path for passing air parallel to the surface on which the display device 1 is arranged is secured. . Since this ventilation path is secured in the entire display device, heat does not accumulate in the housing 2. In addition, the arrow of FIG.9 (b) represents the flow of air.

  As described above, in the display device according to the present embodiment, the housing 2 has the intake port 4 on the bottom surface and the exhaust port 5 on the top surface, and is parallel to the surface on which many display devices 1 are arranged. Since the air can be ventilated, there is no portion where heat is accumulated in the housing 2 of the display device, the temperature control capability of the display device is improved, and an image with high image quality can be obtained.

  In the display device according to the present embodiment, the heater 8 can be provided at the intake port 4, and the cooling fan 6 can be provided at the exhaust port 5. By providing the heating heater 8 at the intake port 4, the air heated by the heating heater 8 can be supplied to the entire inside of the housing 2. Further, by providing the cooling fan 6 at the exhaust port 5, the air in the housing 2 can be quickly exhausted. Therefore, providing the heating heater 8 at the intake port 4 and providing the cooling fan 6 at the exhaust port 5 can further improve the temperature control capability of the display device.

  The display device according to the present embodiment relates to the first embodiment in which the heating unit and the cooling unit are controlled based on the calculation result of the control unit, and the drive condition of the display device is changed based on the calculation result. With respect to the display device, an intake port is added to the bottom surface of the housing and an exhaust port is added to the top surface. However, the present invention in which the intake port is provided on the bottom surface of the housing and the exhaust port is provided on the top surface can be applied to devices other than the display device according to Embodiment 1 or the like.

(Modification)
The display device provided with the exhaust port 5 on the upper surface of the housing 2 shown in the present embodiment has no problem when used in a place where it is not directly exposed to wind and rain even though it is exposed to direct sunlight. . However, when this display device is used outdoors, since the exhaust port 5 is provided on the upper surface of the housing 2, rain enters the housing 2 from the exhaust port 5 in the rain and causes a problem in the display device. It is thought that it is done.

  Therefore, in the display device according to this modification, as shown in FIGS. 9A and 9B, the opening / closing door 9 is provided at the exhaust port 5. By providing the opening / closing door 9 at the exhaust port 5, it is possible to prevent the rain from entering the housing 2 from the exhaust port 5 by closing the opening / closing door 9 in rainy weather. In addition, since the display device is not irradiated with direct sunlight during rainy weather, the internal temperature does not rise so much and the display device can be sufficiently cooled even when the exhaust port 5 is closed.

  As described above, in the display device according to the present modification, the housing 2 further includes the open / close door 9 that can be opened and closed at the exhaust port 5, so that rain or the like entering from the exhaust port 5 by closing the open / close door 9. In addition, the heat of the display device can be efficiently released by opening the open / close door 9 to increase the cooling capacity.

  In addition, the door provided in the exhaust port 5 is not restricted to the one large opening / closing door 9 as shown to Fig.9 (a) and FIG.9 (b), You may be comprised by several doors.

  In addition, the display device according to the present modification controls the heating unit and the cooling unit based on the calculation result of the control unit, and changes the display device driving condition based on the calculation result. An opening / closing door is added to the upper part of the housing. However, the present invention in which an opening / closing door is provided in the upper portion of the housing can be applied to a display device other than the display device according to Embodiment 1 or the like.

(Embodiment 6)
FIG. 10A is a plan view of the display device according to this embodiment, and FIG. 10B is a cross-sectional view of the display device according to this embodiment. Similar to the display device according to the fifth embodiment, the display device according to the present embodiment is provided with an intake port 4 on the bottom surface of the housing 2 and an exhaust port 5 on the top surface. Therefore, the display device according to the present embodiment can also secure a path for ventilating in parallel to the surface on which the display device 1 is arranged. In addition, the arrow of FIG.10 (b) represents the flow of air.

  The display device according to the present embodiment further includes a roof 10 at the top of the housing 2. Since the roof 10 is provided so as to cover the exhaust port 5, the roof 10 has an effect of preventing rain and the like from entering the exhaust port 5 and blocking the direct sunlight irradiated on the upper portion of the display device.

  The temperature rise caused by direct sunlight brings the severest temperature rise in operation for a display device used outdoors. Therefore, providing the roof 10 on the upper part of the display device is an effective structure from the viewpoint of temperature control of the display device.

  As described above, in the display device according to the present embodiment, since the housing 2 is provided with the roof 10 covering the exhaust port 5 at the top, it is possible to prevent rain and the like entering from the exhaust port 5 and display The temperature control capability of the apparatus can be improved.

  The display device according to the present embodiment relates to the first embodiment in which the heating unit and the cooling unit are controlled based on the calculation result of the control unit, and the drive condition of the display device is changed based on the calculation result. A roof is additionally provided on the upper surface of the housing with respect to the display device. However, the present invention in which the roof is provided on the upper surface of the housing can be applied to other than the display device according to Embodiment 1 or the like.

It is the top view and sectional drawing of the display apparatus which concern on Embodiment 1 of this invention. It is a flowchart of the temperature control of the display apparatus which concerns on Embodiment 1 of this invention. It is a flowchart of the temperature control of the display apparatus which concerns on Embodiment 1 of this invention. It is a flowchart of the temperature control of the display apparatus which concerns on Embodiment 2 of this invention. It is the top view and sectional drawing of a display apparatus which concern on Embodiment 3 of this invention. It is a flowchart of the temperature control of the display apparatus which concerns on Embodiment 3 of this invention. It is a top view of the display apparatus which concerns on Embodiment 4 of this invention. It is a flowchart of the temperature control of the display apparatus which concerns on Embodiment 4 of this invention. It is the top view and sectional drawing of a display apparatus which concern on Embodiment 5 of this invention. It is the top view and sectional drawing of a display apparatus which concern on Embodiment 6 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Display device, 2 Housing | casing, 3 Temperature sensor, 4 Intake port, 5 Exhaust port, 6 Cooling fan, 7 Control part, 8 Heating heater, 9 Open / close door, 10 Roof.

Claims (14)

A plurality of display devices arranged in large numbers;
A housing for supporting a plurality of the display devices;
Heating means for heating the display device;
Cooling means for cooling the display device;
A plurality of temperature sensors for measuring the temperature of the display device;
A controller that collects and calculates an output value from the temperature sensor;
The said control part controls the said heating means and the said cooling means based on the result of a calculation, and changes the drive conditions of the said display device based on the result of a calculation, The display apparatus characterized by the above-mentioned.   The control unit calculates an average value of output values from the plurality of temperature sensors, and changes a driving condition of the display device based on the average value as a result of the calculation. The display device described.   The said control part calculates the maximum value of the output value from the said several temperature sensor, and changes the drive condition of the said display device based on the said maximum value which is the result of a calculation. The display device described.   The said control part calculates the minimum value of the output value from the said several temperature sensor, The drive condition of the said display device is changed based on the said minimum value which is the result of calculation, The said control device is characterized by the above-mentioned. The display device described.   The control unit, instead of changing the driving condition of the display device based on the result of the calculation, instead of changing the driving condition of the display device based on the output value from the individual temperature sensor, The display device according to claim 1, wherein the driving condition is changed.   The control unit detects an abnormality of the temperature sensor from the collected output value, and corrects the output value from the temperature sensor in which the abnormality is detected by a predetermined calculation. The display device according to any one of 5.   7. The housing according to claim 1, wherein the housing has an air inlet on a bottom surface and an air outlet on an upper surface, and can ventilate parallel to a surface on which a large number of the display devices are arranged. The display apparatus in any one.   The display device according to claim 7, wherein the casing is provided with the heating unit at the intake port and the cooling unit at the exhaust port.   The display device according to claim 7, wherein the housing further includes a door that can be opened and closed at the exhaust port.   The display device according to claim 7, wherein the casing is provided with a roof covering the exhaust port at an upper portion. A plurality of display devices arranged in large numbers;
A housing that supports a plurality of the display devices,
The display device has an intake port on a bottom surface and an exhaust port on an upper surface, and is capable of ventilating parallel to a surface on which a large number of the display devices are arranged.   The display device according to claim 11, wherein the casing is provided with the heating unit at the intake port and the cooling unit at the exhaust port.   The display device according to claim 11, wherein the housing further includes a door that can be opened and closed at the exhaust port. The display device according to claim 11, wherein the casing is provided with a roof covering the exhaust port at an upper portion.

Images