JP2006169884A - Display device and method for preventing snow accretion of display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device capable of maintaining good visibility without consuming a large amount of power and a method for preventing snow accretion of the display device.
In the present invention, by detecting moisture at each determination point S, it is possible to specify a portion of the display surface 11 where there is snow. Then, when there is snow, the heater areas R1 to R32 in charge of heating the determination point S are specified with reference to the reference table T2, and the heating wires 32 of the specified heater areas R1 to R32 are heated. That is, since power is supplied only to the heating wire 32 that needs to be heated, power consumption can be suppressed.
[Selection] Figure 6

Description

  The present invention relates to a display device that displays road information and the like, and a snow accretion prevention method for the display device.

2. Description of the Related Art Conventionally, as a measure for preventing snow accretion for this type of display device, one that prevents snow from adhering by heating the entire display surface with a heater is known (see, for example, Patent Document 1). ).
According to such a configuration, it is possible to prevent the display surface from being blocked by snow, and it is possible to perform a visible display even during snowfall.
JP 2002-38430 A

However, in the above-described display device, heating by the heater is performed on the entire display surface regardless of the state of snow adhesion, and there is a problem that a large amount of power is consumed in the heater.
The present invention has been made in view of the above problems, and an object of the present invention is to provide a display device that can maintain good visibility without consuming a large amount of power, and a method for preventing snow accretion of the display device.

In order to achieve the above object, in the invention according to claim 1, in a display device for displaying road information and the like,
It is determined that there is a need for heating by the divided heater in charge of heating for each heater area divided into a plurality of display surfaces, determination means for determining the necessity of heating for the heater area, and the determination means. And a heating control means for heating with the divided heater in charge of heating of the heater area.

  In the invention of claim 1 configured as described above, the display surface is provided with divided heaters, and each of them is responsible for heating the display surface for each heater area. The determination means determines the necessity of heating the heater area. And a heating control means can heat the said heater area by making it heat by the said division | segmentation heater in charge of the said heater area determined to have the necessity for a heating.

  In the invention according to claim 2, the determination means includes a plurality of determination points arranged on the display surface, a monitoring means for monitoring the state of the display surface for each determination point, and each determination point is A reference table that defines which of the heater areas belongs, and the necessity for heating is determined for each of the determination points from the monitoring result by the monitoring means, and the reference table is referred to, and the heating necessity is The heater area to which the determination point belongs is specified, and area determination means for determining that there is a need for heating for the specified heater area is provided.

  In the invention of claim 2 configured as described above, a plurality of determination points are arranged on the display surface. And a monitoring means monitors the state of the display surface for every said judgment point. On the other hand, the reference table defines which of the heater areas each determination point belongs to. The area determination unit determines the necessity of heating for each determination point from the monitoring result of the monitoring unit. And the said area determination means specifies the said heater area to which the said determination point determined that there exists a necessity for a heating with reference to a reference table. Furthermore, the area determination means determines that the heater area specified here is the heater area that needs to be heated.

Furthermore, in the invention concerning Claim 3, the said monitoring means monitors the presence or absence of the water | moisture content in the said determination point, It has the structure which determines that the said area determination means determines the necessity for a heating about the said determination point with the water | moisture content. .
In the invention of claim 3 configured as described above, it is determined that the determination point needs to be heated when there is moisture at the determination point. Thereby, it can be detected that the visibility around the determination point on the display surface is deteriorated by the snow adhering to the display surface, and the necessity of heating can be determined.

  Moreover, in the invention concerning Claim 4, the said determination point is arrange | positioned at the space | interval which can be short-circuited with a water drop in the same determination point, and the several electric wire from which the resistance value between each is monitored by the said monitoring means In addition, the monitoring means is configured to determine that there is moisture at the determination point when the resistance value decreases.

  In the invention of claim 4 configured as described above, the determination point includes a plurality of electric wires. This electric wire is installed in the space | interval which can mutually short-circuit with a water drop, and the resistance value between each other is monitored by the said monitoring means. Then, the monitoring means determines that there is moisture at the determination point when the resistance value decreases. That is, it is possible to detect that snow has adhered between the electric wires when the resistance value between the electric wires has decreased.

Furthermore, in the invention concerning Claim 5, the said determination means comprises the temperature detection means which detects temperature, and when the detected temperature is low, the structure which determines the necessity for a heating with respect to the said heater area is comprised. It is as.
In the invention of claim 5 configured as described above, the air temperature detecting means detects the air temperature, and when the air temperature is low, the necessity of heating is determined for the heater area. Thereby, heating can be performed by the divided heater in a situation where the possibility of snowfall is high.

Furthermore, in the invention according to claim 6, the heating control means is configured to perform heating in advance by the divided heater when the monitoring means monitors the presence or absence of moisture at the determination point.
In the invention of claim 6 configured as described above, a small amount of water can be evaporated and removed from the determination point by heating with the divided heater in advance. That is, a small amount of moisture such as frost or dew that does not significantly reduce the visibility of the display surface is detected by the monitoring means, and the moisture is heated and evaporated by the divided heater to prevent the monitoring means from malfunctioning. Can do.

  The above-described method can also be applied as a method for preventing snow accretion of a display device. In the invention according to claim 7, the same operation is basically achieved. Of course, it is also possible to make the structure described in claims 2 to 6 correspond to the method of claim 7.

As described above, according to the inventions according to claim 1 and claim 7, it is possible to provide a display device capable of maintaining good visibility without consuming a large amount of power, and a method for preventing snow accretion of the display device. it can.
According to the invention concerning Claim 2, only the heater area which needs a heating can be heated.
According to the third aspect of the present invention, it is possible to detect moisture adhering to a part of the display surface, remove the moisture by heating, and recover the visibility of the display surface.

According to the fourth aspect of the invention, moisture can be detected with a simple configuration.
According to the fifth aspect of the invention, the divided heater can be heated only in a situation where the possibility of snowfall is high.
According to the invention of claim 6, it is possible to prevent the divided heater from malfunctioning and being heated when a small amount of moisture such as frost or dew is adhered.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of display device:
(2) Operation of display device:
(3) Summary:

(1) Configuration of display device:
FIG. 1 shows the appearance of a display device according to the present invention. In the figure, a display device 10 is a device that is attached to a pillar standing on the side of a road, and displays road information and the like. A display unit to be described later is disposed behind the display surface 11, and a plurality of LEDs (light emitting diodes) are disposed as light emitting elements in the display unit. And a character and a pattern can be displayed on the display surface 11 by lighting any of these LED. The enlarged view A is a diagram schematically showing a part of the LED in an enlarged manner, in which pixels P composed of red LEDs (R) and yellow-green LEDs (G) are arranged in a matrix. When only the red LED is lit, red and yellow-green LED are lit, and yellow-green, and when the red and yellow-green LEDs are lit, orange characters and designs can be displayed. An outside air temperature sensor 50 is attached outside the display device 10. The outside air temperature sensor 50 can use, for example, a thermistor or a thermocouple.

  FIG. 2 schematically shows a vertical section of the display device 10. In the figure, display units 20, 20, 20... In which a plurality of LEDs 21, 21, 21... Are arranged in a matrix are arranged in the height direction. On the front surface of the display units 20, 20, 20..., A rectangular plate-shaped glass heater 30 that forms the display surface 11 of the display device 10 is held by the housing 12.

  FIG. 3 is a view of the glass heater 30 as viewed obliquely. In the figure, the glass heater 30 has a structure in which heating wires 32, 32, 32. Each of the heating wires 32, 32, 32... Meanders inside a substantially rectangular outer shape, and is arranged adjacent to each other in a matrix. The heating wires 32, 32, 32,... Are made of an electrically conductive metal such as nichrome or cantal, and are independently connected to terminals 32a, 32b, 32c is derived. Each of the heating wires 32, 32, 32... Has a continuous conductive path between the terminals 32a, 32b at both ends, and by applying a voltage between the terminals 32a, 32b, each heating wire 32, 32,. Currents can be individually supplied to 32. Further, each heating wire 32, 32, 32... Is connected to the terminal 32c at an intermediate position of the path, and by applying a voltage between the terminals 32b, 32c, each heating wire 32, 32, 32. .. About 20% of the current flowing through all the paths can be passed. The heater substrate 33 connected to the terminals 32a, 32b, 33c derived from all the heating wires 32, 32, 32... Is provided with a power supply circuit and a switch circuit (not shown), which are designated to a control unit described later. It is possible to selectively pass a current through the heated wires 32, 32, 32.

  When a voltage is applied between the terminals 32a, 32b of the heating wires 32, 32, 32..., A current flows through the heating wires 32, 32, 32. Then, the substantially rectangular heater areas R, R, R... That are the portions sandwiching the heating wires 32, 32, 32. That is, each heating wire 32, 32, 32... Is a divided heater in charge of heating a plurality of heater areas R, R, R. it can. Further, the heater areas R, R, R... Can be partially heated by applying a voltage between the terminals 32 b, 32 c of the heating wires 32, 32, 32.

  In this embodiment, the glass heater 30 is heated by the heating wires 32, 32, 32..., But may be heated by other heating materials. Further, the heat source is not limited to a linear heat source, and may be a heat source having another shape. For example, a metal oxide having electrothermal properties may be kneaded together with a predetermined paste and printed in a rectangular shape divided with respect to the plate glasses 31 and 31. By doing in this way, uniform heating can be performed in the heater areas R, R, R. Of course, the heating wire itself is thin and does not interfere with visual recognition. However, in order not to impair the visibility of the display surface 11, selection of a light-transmitting paste material and setting for minimizing the printed film thickness are performed. It is desirable.

  In FIG. 2, a moisture detector 40 is provided on the front side of the glass heater 30. FIG. 4 shows a part of the moisture detector 40 viewed from an oblique direction. In the figure, only a part of the moisture detector 40 is shown, but in reality, the parts shown in the drawing are continuous in the vertical and horizontal directions, and the outer shape of the moisture detector 40 is substantially the same as the glass heater 30. Has been. And it is hold | maintained at the housing | casing 12 so that it may closely_contact | adhere to the glass heater 30 from the front. The vertical electric wires 41, 41, 41,... Are placed above the laminated film (front in FIG. 2) sandwiched between the two insulating films 42a, 42b. The moisture detector 40 is formed by overlapping the laminated films sandwiched between the two insulating films 41a and 41b. Thus, when the moisture detector 40 is viewed from above (front in FIG. 2), the vertical electric wires 41, 41, 41... And the horizontal electric wires 42, 42, 42. Can be crossed. Since the vertical electric wires 41, 41, 41... And the horizontal electric wires 42, 42, 42... Are arranged at equal intervals, they intersect in a square lattice pattern.

  However, since the insulating films 41b and 42a are interposed between the vertical electric wires 41, 41, 41... And the horizontal electric wires 42, 42, 42. Absent. The total thickness of the insulating films 41b and 42a is within 2 mm. Further, the determination points S, S, S are points where the vertical electric wires 41, 41, 41... And the horizontal electric wires 42, 42, 42. ... and so on. In each judgment point S, S, S..., Cylindrical notches 44, 44, 44... Penetrating the insulating films 41a, 41b, 42a, 42b are formed, The electric wires 41, 41, 41... In the direction and the electric wires 42, 42, 42.

  Therefore, in each judgment point S, S, S ..., it is not the insulating films 41b, 42a, but the vertical electric wires 41, 41, 41 ... and the horizontal electric wires 42, 42,. 42... Face each other at a predetermined interval. The terminals of the vertical electric wires 41, 41, 41... And the horizontal electric wires 42, 42, 42... Are led out independently to the detection substrate 43 provided in the moisture detector 40. The detection substrate 43 is provided with a power supply circuit (not shown), a switch circuit, and a resistance measurement circuit corresponding to the monitoring means of the present invention. It is possible to measure the resistance value between them.

  FIG. 5 shows a configuration of a control unit that controls the display device 10. In the figure, the display device 10 has a control unit 60 for controlling characters and symbols to be displayed on the display surface 11, and the control unit 60 is connected to each display unit 20, 20, 20. . The control unit 60 is connected to an outside air temperature sensor 50 provided outside. Each display unit 20, 20, 20... Is equipped with a shift register 31b. The shift register 31b is a storage device that sequentially transmits digital data to an adjacent register in synchronization with an input clock, and a register corresponds to each color LED. In the present embodiment, the corresponding LED is turned on when the digital data stored in the register is “1”, and the corresponding LED is turned off when the digital data is “0”.

  In order to display characters and symbols on the entire display surface 11, each display unit 20, 20, 20... Acquires digital data serially transferred from the control unit 60 by a shift register, and each LED display unit Data for the entire screen is transferred to the shift register and stored, and characters and symbols are displayed on the display surface 11.

The control unit 60 includes a CPU 61, a control program memory 62, a display data memory 63, a ROM 64, and a timer 65. The control program memory 62 is a storage medium that stores a control program M for controlling the display device 10, and the CPU 61 executes the control program M while using the display data memory 63 as a work area. The control program M includes a display control unit M1, a determination unit M2, a heating control unit M3, and an area determination unit M4. The display control unit M1 creates the digital data for executing lighting of pixels corresponding to characters and symbols and lighting of pixels corresponding to the background, and controls the lighting timing of the LEDs 21, 21, 21. Processing to create a signal is performed. Also,
When the display control unit M1 creates the digital data, display data 64a indicating characters and symbols to be displayed stored in the ROM 64 is used.

  The determining unit M2 refers to the table T1 stored in the ROM 64, and the vertical electric wires 41, 41, 41... And the horizontal electric wires 42, 42, 42. • Generate a control signal to pass current through Details of the table T1 will be described later. The control signal is input to the detection substrate 43 of the moisture detector 40 via a detector interface (I / F) 66 provided between the moisture detector 40 and the CPU 61. In the detection board 43, the switch circuit is operated based on the control signal, and the electric wires 41, 41, 41..., 42, 42, 42. It is possible. Further, the resistance measurement circuit of the detection substrate 43 is a resistance value at each of the determination points S, S, S... When current is passed through the electric wires 41, 41, 41. , And the resistance value is output to the CPU 61 via the detector I / F 66. When the resistance value is input, the determination unit M2 specifies determination points S, S, S... That need to be heated.

  The area determination unit M4 refers to the reference table T2 stored in the ROM 64 and the heater areas R, R, R to which the determination points S, S, S,. ... is specified. Details of the reference table T2 will be described later. The heating control unit M3 generates a control signal for heating the heater areas R, R, R... Specified by the area determination unit M4. This control signal is input to the heater substrate 33 of the glass heater 30 via the heater interface (I / F) 67. Then, by operating the switch circuit of the heater substrate 33 based on the control signal, it is possible to switch the terminals 32a, 32b of the heating wires 32, 32, 32... Supplied with power from the power supply circuit. It has become.

  Further, the heating control unit M3 stores information on the terminals 32b and 32c that need to be energized in order to heat the positions corresponding to all the determination points S, S, S. The heating control unit M3 outputs a control signal for applying a voltage between the terminals 32b and 32c as necessary. That is, when a small amount of water adhering to all the determination points S, S, S... Is evaporated by heating the positions corresponding to all the determination points S, S, S. , Current is partially applied to each heating wire 32, 32, 32..., And only portions corresponding to all judgment points S, S, S... In each heater area R, R, R. To heat up.

(2) Operation of display device:
FIG. 6 shows the flow of the snow accretion prevention process performed by the display device 10. Each process of the figure is realized by the CPU 61 executing various arithmetic processes according to the control program stored in the control program memory 62. In step S100, the outside air temperature sensor 50 detects the outside air temperature. Note that step S100 is executed by the timer 65 every 15 minutes in the winter period. Further, step S100 is forcibly started even during execution of steps S110 to S160 described later. In step S110, it is confirmed that the outside air temperature is 3 degrees or less, and when it is not 3 degrees or less, the process is stopped. That is, assuming that the temperature is high and the possibility of snowfall on the display surface 11 is low, the subsequent snowfall prevention processing is not performed. The outside air temperature at which it is determined that the possibility of snowfall is low is not limited to 3 degrees, and may be a temperature higher than 3 degrees or a low temperature depending on the snow quality. By executing step S110, it can be confirmed that the temperature is low. Therefore, in a state where this condition is satisfied, it can be said that there is a high possibility that the moisture adhering to the display surface 11 is due to snow.

  Furthermore, in step S120, the positions corresponding to all the determination points S, S, S... In the glass heater 30 are heated. That is, a voltage is applied to the terminals 32b and 32c that need to be energized to heat the position. Thereby, only the site | part corresponding to all the determination points S, S, S ... in each heater area R, R, R ... is heated. Then, the determination points S, S, S... Where the vertical electric wires 41, 41, 41... Face each other and the horizontal electric wires 42, 42, 42. , S ... evaporates moisture. Therefore, moisture such as frost and dew adhering to the determination point S can be temporarily removed. Moreover, since only the site | part corresponding to all the judgment points S, S, S ... in each heater area R, R, R ... is heated, power consumption can be suppressed.

In step S130, the moisture detector 40 detects moisture. FIG. 7 shows a view of the moisture detector 40 as viewed from the front. In the figure, the longitudinal direction of the electric wire 41,41,41 ... and lateral wires 42,42,42 ... to identify individually, V ₁ a longitudinal direction of the electric wire from left to right, V ₂ , V ₃ ..., And the horizontal electric wires are represented as H ₁ , H ₂ , H ₃ . A determination point formed by intersecting the electric wire V ₁ and the electric wire H ₁ is represented as a determination point S _1-1, and a determination point formed by intersecting the electric wire V ₂ and the electric wire H ₁ is determined by the determination point S. It shall be expressed as _2-1 .

  In FIG. 7, the determination points S are distributed in a uniform grid shape on the front side of the display surface 11. In the figure, the determination point S is exaggerated. Actually, since the electric wires V and H are extremely thin with respect to the display surface 11, the visibility of the display surface 11 is not affected. FIG. 8 schematically shows a procedure in which the moisture detector 40 performs moisture detection. In the figure, the order of the determination points S for performing moisture detection is shown, and the electric wires V and H to be energized at that time are shown in adjacent columns. A table T1 showing a procedure for detecting moisture by the moisture detector 40 is stored in the ROM 64, and is read out and used by the CPU 61 as appropriate.

In the table T1, defined so as to perform all the determination point _{S 1-1 → S 1-2 → S 1-3} → S 1-4 moisture detection in the order of ·· S _1-20 → S _2-1 ··· Has been. And when detecting the water | moisture content of each judgment point S, it is shown that an electric current is sent with the two electric wires V and H which cross | intersect at the said judgment point S. FIG. The control unit 60 sequentially switches the switch circuit of the detection substrate 43 so that the current flows according to the procedure shown in the table T1. And the resistance measurement circuit as a monitoring means of this invention measures the resistance value in that case.

  When the judgment point S is dry, only air exists between the electric wires V and H, and the resistance value between the two becomes extremely large. On the other hand, when moisture adheres to the determination point S, the electric wires V and H are short-circuited, and the resistance value between the two is reduced. Therefore, when the resistance values of the electric wires V and H are low, it can be seen that moisture adheres to the determination point S formed by intersecting the electric wires V and H. Therefore, it is possible to determine the distribution state of moisture adhering to the entire display surface 11 by passing currents through the wires V and H according to the table T1 and measuring the resistance value.

  Since the determination point S is heated in advance in step S120 to evaporate the moisture, the possibility that frost, dew, etc. is detected as moisture here is reduced. On the other hand, when it is snowing on the front side of the display surface 11, since the determination point S is covered with snow, moisture formed by melting snow in step S 120 remains at the determination point S. . Therefore, it is possible to reliably detect a snowfall state on the display surface 11.

  In step S140, it is determined whether or not there is a determination point S in which moisture is detected. If there is no determination point S in which moisture is detected, the snow accretion prevention process is terminated. That is, the processing is interrupted on the assumption that there is no snow on the display surface 11 and there is no problem with visibility. Of course, since step S100 is performed every 15 minutes, it is possible to melt snow on the snow accumulated thereafter. On the other hand, if it is determined in step S140 that there is a determination point S at which moisture is detected, it is determined that there is a need for melting snow for the determination point S, and the determination point S is stored. In step S150, the heater area R in charge of heating around the determination point S is specified. That is, the heater area R in need of heating is specified.

  FIG. 9 schematically shows an arrangement state of the determination points S and the heater areas R on the display surface 11. In the figure, rectangular heater areas R1 to R32 are arranged in a matrix with respect to the determination points S arranged in a grid on the front side of the display surface 11. Heater areas R1 to R32 of a total of 32 areas of 4 rows × 8 columns are provided. Substantially, 32 heating wires 32, 32, 32... Are arranged in a matrix corresponding to each heater area R1 to R32.

FIG. 10 shows a reference table T2 that is referred to when the heater area R is specified in step S150. Note that the reference table T2 is stored in the ROM 64, and is read and used as appropriate by the CPU 61. In the reference table T2, all the heater areas R1 to R32 are shown, and the determination points S corresponding to each of the heater areas are classified and described. For example, decision point S which is responsible for heating the heating wire of the heater area R1 _{is, S 1-1 ~S 1-5, S 2-1} ~S 2-5, S 3-1 ~S 3-5, S _4-1 to S _4-5, it is understood that the S _5-1 to S _5-5. By referring to such a reference table T2, it is possible to identify the heater areas R1 to R32 to which the determination point S determined to be necessary for heating belongs. If it is determined that there is a need to heat a plurality of determination points S at the same time, the heater areas R1 to R32 to which each belongs are specified. In addition, in order to efficiently melt snow adhering to the heater areas R1 to R32 to which the determination points S determined to be heated belong, heating is performed in any combination with other heater areas R1 to R32. You may do it. In that case, an arbitrary combination may be defined in the reference table T2.

  In step S160, the heating wires 32, 32, 32... Corresponding to the heater areas R1 to R32 specified in step S150 are energized for 3 minutes. By doing so, it is possible to heat only the heater areas R1 to R32 where snow accumulates on the display surface 11 and snow melting is necessary. Therefore, the visibility of the display surface 11 is ensured. In step S160, only the heating wires 32, 32, 32... That need to be heated are energized, so that power consumption can be suppressed. When heating for 3 minutes is completed in step S160, moisture is detected again in step S130. That is, in step S160, it is determined whether or not snow melting has been sufficiently performed. When the snow melting is insufficient, the heater areas R1 to R32 are identified and heated again.

  By repeating the above processing, snow melting on the display surface 11 can be completed. In the present embodiment, since the correspondence relationship between the determination point S and the heater areas R1 to R32 can be acquired from the reference table T2, the resolution of the heater areas R1 to R32 on the display surface 11 and the resolution of the determination point S Are not necessarily matched. Therefore, precise moisture detection can be performed at a large number of determination points S without dividing the heater areas R1 to R32 finely.

  It is to be noted that the present invention is intended to detect an area that has snowed on the display surface, and to suppress power consumption by energizing only the glass heater 30 with respect to the detected area, thereby ensuring good visual recognition. is there.

  Therefore, in the present embodiment, the start condition is that the temperature is below a certain level by the outside air temperature sensor 50, but step S100 and step S110 in FIG. 2 are omitted, and a timer setting signal in winter or a remote control signal from the outside Thus, the processing after step S120 may be periodically executed. Conversely, the processing after step S120 may be executed by a signal from a known snowfall meter.

  Further, in the present embodiment, a display device using an LED as a light emitting element has been described as an example. However, the present invention is not limited to an LED, and a variable type of any method currently used or developed in the future. Alternatively, the present invention can be applied to a fixed display device.

(3) Summary:
As described above, in the present invention, by detecting moisture at each determination point S, it is possible to specify a site where there is snow on the display surface 11. Then, when there is snow, the heater areas R1 to R32 in charge of heating the determination point S are specified with reference to the reference table T2, and the heating wires 32 of the specified heater areas R1 to R32 are heated. That is, since power is supplied only to the heating wire 32 that needs to be heated, power consumption can be suppressed.

1 is an external view of a display device according to the present invention. It is a vertical sectional view of a display device according to the present invention. It is a perspective view of the glass heater concerning this invention. It is a perspective view of the moisture detector concerning the present invention. It is a block diagram of the display apparatus concerning this invention. It is a flowchart of the snow accretion prevention process concerning this invention. It is a front view of the moisture detector concerning the present invention. It is a table which shows the flow of the moisture detection concerning this invention. It is a front view of the moisture detector and glass heater concerning the present invention. It is a reference table concerning the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Display apparatus 11 ... Display surface 12 ... Case 20 ... Display unit 21 ... LED
DESCRIPTION OF SYMBOLS 30 ... Glass heater 31 ... Sheet glass 32 ... Heating wire 33 ... Heater substrate 40 ... Moisture detector 43 ... Detection substrate 44 ... Notch 50 ... Outside temperature sensor 60 ... Control part 61 ... CPU
62 ... Control program memory 63 ... Display data memory 64a ... Display data 65 ... Timer 66 ... Detector interface 67 ... Heater interface M ... Control program M1 ... Display control unit M2 ... Determination unit M3 ... Heating control unit M4 ... Area determination unit R ... heater area S ... determination point T1 ... table T2 ... reference tables V, H (41, 42) ... electric wires

Claims (7)

In a display device that displays road information, etc.
A divided heater in charge of heating for each heater area divided into a plurality of display surfaces;
Determination means for determining the necessity of heating for the heater area;
A display device comprising: a heating control unit that performs heating by the divided heater that is in charge of heating the heater area that is determined to be heated by the determination unit. The determination means is
A plurality of determination points arranged on the display surface;
Monitoring means for monitoring the state of the display surface for each judgment point;
A reference table that defines which of each heater area each decision point belongs to;
While determining the necessity of heating for every said judgment point from the monitoring result by the said monitoring means, with reference to the said reference table, the said heater area to which the said judgment point with the said heating need belongs was specified, and the same The display device according to claim 1, further comprising area determination means for determining that the heater area needs to be heated. The monitoring means monitors the presence or absence of moisture at the determination point,
The display device according to claim 2, wherein the area determination unit determines that there is a need for heating at the determination point having moisture. The determination point includes a plurality of electric wires that are arranged at intervals that can be short-circuited by water droplets at the determination point, and whose resistance value is monitored by the monitoring means,
The display device according to claim 3, wherein the monitoring unit determines that there is moisture at the determination point when the resistance value decreases. The determination means is
While equipped with a temperature detection means for detecting the temperature,
5. The display device according to claim 1, wherein the necessity of heating is determined for the heater area when the detected temperature is low.   6. The display according to claim 3, wherein the heating control means heats the divided heater in advance when the monitoring means monitors the presence or absence of moisture at the determination point. apparatus. In a method for preventing snow accretion of a display device that displays road information etc.,
A determination step of determining the necessity of heating for the heater area in which the divided heaters are each responsible for heating the display surface;
And a heating control step of heating by the divided heater in charge of heating of the heater area determined to be heated in the determination step. .

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