JP4825851B2 - Display warning light - Google Patents

Description

  In the present invention, light emitting element unit bar displays in which light emitting elements such as LEDs (light emitting diodes) are linearly arranged at regular intervals are arranged at equal intervals in the circumferential direction from the center to the outer periphery. More specifically, the present invention relates to a scroll warning light used in road construction or the like.

  As a scroll indicator lamp using light emitting elements such as LEDs, dots in which a plurality of light emitting elements are arranged in a straight line vertically at regular intervals and arranged horizontally and at the same intervals as the intervals between the light emitting elements Matrix type display panels have been put into practical use. In general, this type of display panel sequentially creates character string data in a bitmap format that constitutes one character with, for example, 16 × 16 dots, and scrolls and displays the character string in the horizontal direction at a constant speed. In order to increase the number of characters to be displayed in the scroll indicator light that moves the character string in the horizontal direction in this way, it is necessary to significantly increase the number of horizontal dots (the number of light emitting elements) on the display panel. The length of the panel is increased and the cost is significantly increased.

Therefore, a light emitting element unit bar display in which light emitting elements are arranged in a straight line at regular intervals using an optical illusion (afterimage) is spaced at least five times the distance between the light emitting elements in the horizontal direction. Assuming that the light emitting element unit bar display is also present in the virtual space between the light emitting element unit bar displays, for example, a character string in a bitmap format in which one character is composed of 16 × 16 dots, for example. A scroll display device that sequentially supplies image data and performs scroll display that moves in the horizontal direction has been proposed (see, for example, Patent Document 1). According to this scroll display device, the light emitting elements at predetermined positions of the light emitting element unit bar display sequentially emit light based on the image data, and scroll display is performed. As a result, only one column of the five or more columns of light emitting element unit bar indicators emits light, but by increasing the scrolling speed to some extent, the image data (character string) in the virtual space can also be recognized. .
JP-A-8-179717

  The scroll display device according to the above prior art has an effect that a large-sized display device can be realized at a low price, but there is room for improvement in the following points. That is, the scroll display device has a structure in which vertical unit bar indicators are arranged in parallel in a plurality of rows in the horizontal direction at intervals of 5 times or more of the light emitting element intervals. It is not suitable for display warning lights that are limited by the installation location and size.

  In addition, in the case of a display warning light for road construction, the power supply destination often becomes a problem. This is because even when the power generation device is mounted on the construction vehicle, it is necessary to lay the power cable from the construction vehicle to the installation location of the display device, and it is also necessary to manage the power cable.

  The present invention has been made in view of the above points, and even if there is a restriction on the size and installation location for road construction, etc., it is easy to downsize, and it is possible to scroll through necessary character information and images representing the construction in progress. The purpose is to provide a display warning light that can be displayed. A second object of the present invention is to provide a display warning lamp including a photovoltaic power generation panel device that can be lit for a long time without receiving power supply when installed on a road or the like.

  In order to solve the above object, a display warning light according to the present invention is characterized by the following items (1) to (5).

(1) The n rows of light emitting element unit bars in which S light emitting elements are linearly arranged at a constant interval t are arranged at equal intervals (360 ° / n) in the circumferential direction from the central portion to the outer peripheral portion and along the radial direction. And the interval on the outermost peripheral side of adjacent light emitting element unit bars is set to an integral multiple of the t.

(2) The number of image data to be displayed by the light emitting elements in each light emitting element unit bar includes the outer side data according to the radial distance from the circular center position of the light emitting elements in each stage of the light emitting element unit bar. The data in the virtual display area between the light emitting element unit bars is set to m on the basis of the outermost peripheral data, and the same data is duplicated on the inner peripheral side while increasing in steps compared to the peripheral data. Thus, the number of data is set to m.

(3) The image data to be displayed is composed of bitmap format image data including virtual display area data m between the light emitting element unit bars.

(4) The image memory is read-accessed, and the read s number of column data is written to the light point corresponding to the position of the first light emitting element unit bar, and thereafter sequentially corresponds to the position of each light emitting element unit bar. The column data read from the image memory is written to the write point. Here, each column data is latched and output to the light emitting element of each light emitting element unit bar and displayed. In this state, 1 is added to the scroll point to prepare for the next display, and scroll display is performed by repeating the above procedure.

(5) The image data is distributed to a drive circuit of each light emitting element unit bar via a shift register, and a central control device for controlling the image data as a whole and performing scroll display is provided.

  According to the display warning lights specified by the above items (1) to (5), for example, image data in bitmap format including a character string of “caution during construction” and a figure indicating that construction is underway is arranged in the circumferential direction. It distributes with respect to the light emitting element of each light emitting element unit bar arranged at equal intervals, and outputs it simultaneously. At this time, the amount of image data output to the light emitting element on the outer peripheral side is larger than the light emitting element on the inner peripheral side of each light emitting element unit bar, and the time that is output to the light emitting element after being latched once The (light emission interval) becomes longer toward the outer peripheral side.

  Further, the image data is simultaneously output to the light emitting element unit bars in each column with an interval (m + 1) of the number m of data in the virtual display area between one light emitting element unit bar and the next light emitting element unit bar. Then, after sequentially updating to the next image data, the updated data is output, and at the same time, the data before the update is moved to the virtual display area and scroll-displayed.

  In other words, the above image data is a virtual space between the light emitting element unit bars by scrolling at a constant speed in the same direction (for example, clockwise) in units of data on the same circumference (light emitting element position of each stage). Although the entire image data including the image data (character string) in the (virtual display area) is clearly recognized, the amount of image data (data amount) on the same circumference (each stage) It is proportional to the distance in the radial direction from the center position, and increases from the inner peripheral side toward the outer peripheral side. However, the outermost data is basically set to m, and the same data is duplicated on the inner peripheral side where the number of data is reduced compared to the outer peripheral side in order to make it equal to the outermost data number m. It is set. For this reason, when scrolling, the data appears to change less as it goes to the inner periphery. In addition, the time interval of the image data output to each light emitting element unit bar seems to be longer on the outer peripheral side than on the inner peripheral side. As a result, the distance that the display image is scrolled (shifted) toward the outer peripheral side between the light emitting element unit bars in each column in the circumferential direction appears to be larger.

  As described in claim 2, it can be specified by adding the following items (6) and (7) to the items (1) to (5) of the display warning light described in claim 1.

  (6) A circular base on which the n rows of the light emitting element unit bars are arranged is provided on both front and rear surfaces of the display warning light main body.

  (7) A photovoltaic power generation panel device is provided on the top surface of the display warning light body, a charging battery is built in the display warning light body, and the battery is charged with power generated by the photovoltaic power generation panel device. To do.

  As described above, by providing the items (6) and (7) as components, power is generated from the photovoltaic power generation panel device by receiving sunlight, and the generated power is stored (charged) in the battery. The And, in the operating state, if the amount of power generated from the photovoltaic power generation panel device exceeds the amount of power required for the light emission of the light emitting elements of the light emitting element unit bar and the scroll display of the image data, the excess amount of power is stored in the battery. If the battery is charged and the amount of electric power is not satisfied, the shortage of electric power is compensated from the battery.

  As described in claim 3, the item (1) to (7) of the display warning light described in claim 2 is specified by adding the following item (8).

  (8) Power consumption of each light emitting element in the light emitting element unit bar is controlled based on a voltage value generated in the photovoltaic power generation panel device.

  As described above, by providing the above item (8) as a component, it is determined that the voltage generated by the photovoltaic power generation panel device is lower than the reference value at night, and each light emitting element in the light emitting element unit bar display If the voltage value is higher than the preset reference value, it will be judged as daytime and the power consumption of each light emitting element in the light emitting element unit bar will be increased, so the image data of the display warning light will always be displayed in an easy-to-read manner. In addition, power consumption can be minimized.

  According to the present invention, it is possible to perform scroll display in which a fine image of a large size can be visually recognized by a relatively small number of light emitting elements such as LEDs, and this scroll display can be performed in various apparatus forms under various circumstances. realizable. In any case, a circular display panel with a plurality of rows of light emitting element unit bars at equal angles (rotation angles) in the circumferential direction compared to a conventional rectangular dot matrix display panel that is long and continuous in the horizontal direction Therefore, it can be compact and downsized, does not take up installation space, can display image data endlessly, and can greatly reduce the cost of the device in terms of fine display performance and display size. it can.

  Hereinafter, embodiments of the display warning lamp of the present invention will be described with reference to the drawings.

  FIG. 5 is an explanatory view showing a state in which the circular cover in front of the display warning light of FIG. 1 (front view showing an embodiment of the display warning light) is removed, and FIG. 6 is a schematic diagram schematically showing a display mode of image data. In the figure, it is also displayed in a virtual space portion that is not actually displayed and represents a state visible to human eyes. FIG. 7 is a block diagram of the display warning light of FIG. 1 and a flow diagram of the data transmission system.

  A data transmission system according to an embodiment of the present invention is shown in FIG. In this example, the LED (light emitting element) unit bar 3 is configured by linearly arranging eight LEDs (light emitting elements) 2 forming a main part of the scroll display device 1 at a constant interval t. In this example, 12 rows of LED unit bars 3A, 3B, 3C,... 3L are centered on the circular display base 2 at equal intervals in the circumferential direction (360 ° / 12 = 30 °) and along the radial direction. It arranges from the part to the outer peripheral part. An 8-bit LED driver (drive circuit) 7 is attached to each LED 2 of each LED unit bar 3A to 3L. In this example, the driver 7 integrates an 8-bit shift register (not shown) and the LED data latch 8.

  Each driver 7 is connected to the data output of the image memory 5 via a central control unit (CPU) 6 and operates as follows in synchronization with a clock from a timing generation circuit (not shown).

  That is, in this example, it is assumed that image data of a bitmap-format character string in which one character is composed of 8 × 9 bits is stored in the image memory 5. The 7-bit data in each column of the image data is referred to as column data, and numbers such as D1, D2, D3,.

  The central control unit (CPU) 6 reads each column data of the image data stored in advance from the image memory 5 and inputs it to each driver 7. The timing generation circuit supplies latch signals to all the drivers 7 at once every time 8-bit column information of eight column data is read from the image memory 5. That is, the data 8 of each row of image data is fixed (latched) to the data latch 8 immediately before the data is sequentially supplied to the driver 7 of each row and the eight LEDs 2 of the LED unit bar 3 are output to the driver 7. Display drive according to bit string data. Further, the shift register (not shown) outputs the column data fixed by the data latch 8 to the LEDs 2 of each stage of the LED unit bar 3 by the driver 7, and then sends them side by side. That is, the shift register converts the column data sent from the image memory 5 from a parallel state to a serial state from a series of continuous column data, sends the column data to the data latch 8 continuously, and the column data latched by the data latch 8 Is output to the LED 2 via the driver 7 and at the same time the column data of the shift register is rewritten to the next column data, thereby scrolling the data one after another in the circumferential direction.

  At the same time, the following control is performed by the central controller 6 due to the difference in data amount between the outer peripheral side and the inner peripheral side input to the LEDs 2 of each stage of the LED unit bar 3. Specifically, as shown in FIG. 7, in the first stage of the outermost circumference and the eighth stage of the innermost circumference, the LED 2 of the adjacent LED unit bar 3 and the LED 2 of the LED unit bar 3 are on the same circumference. The data amount is varied according to the distance x1 and the distance x8 between the LED 2 of the LED unit bar 3 and the LED 2 of the LED unit bar 3 on the same circumference. The distance x1 and the distance x8 are respectively proportional to the radial dimensions r1 and r8 from the center position of the circular display substrate 4. That is, the virtual data amount (number) m increases stepwise from the eighth stage (lowermost stage) of the LED unit bar 3 to the LED2 of the first stage (uppermost stage). In other words, the virtual data amount m between the same circumference of each stage of the circular display substrate 4 corresponds to the radial distance r from the center position to the LED 2 of each stage of the LED unit bar 3. However, the number of data is increased to m so that the distance between the uppermost rows is the same as the basic data number m, and the distance between the lowermost rows is the same distance between the uppermost rows along the circumferential direction. Expanded state. The column data existing at the distance x1 between the uppermost (first) levels of adjacent LED unit bars 3 is, for example, four (D1, D2, D3, D4), and the distance between the lowermost (eighth) levels. Assuming that the number of column data existing at x8 is two (D2 and D3), for example, in the expanded state of a rectangle, the first stage remains D1, D2, D3, and D4, but the eighth stage is D2. -By repeating the same data as D2, D3 and D3, the number of data (amount) is made common to m. In the intermediate part (between the second stage and the seventh stage), part of the data is repeated so that the same number as the uppermost stage is four. For example, assume that the first stage data is 10 bits, the second stage is 9 bits, the third stage is 8 bits,..., The eighth stage is 3 bits, and 10-bit data is sequentially input per second. In this case, 10 data (whether LED2 emits or does not emit light) is input in the first stage, but only 3 data are input in the eighth stage, so the remaining 7 times are 3 each. Data will be duplicated. In other words, in the first-stage LED 2 and the eighth-stage LED 2, the distance (interval) x of the virtual display area to the next LED unit bar 3 adjacent in the circumferential direction is wide from the first stage to the eighth stage. Therefore, the distance to which the image data is shifted (scrolled) according to the wide or narrow interval is considerably larger in the first stage than in the eighth stage, and from the first stage to the eighth stage. It is getting smaller step by step. In other words, the time interval at which the LED 2 is driven (light emission) from the outermost 1st stage LED2 to the innermost 8th stage LED2 is as if the 8th stage was shorter than the 1st stage. appear. Visually, the LED 2 in the seventh stage (innermost circumference) has a smaller scroll amount for scroll display than the first stage (outermost circumference) and continues in the same circumferential direction as shown in FIG. The interval between the light emitting points of the LED 2 that looks like this closes. All such operations (controls) are performed by the central controller 6.

  As described above, the number of image data of pixel data increases from the inner circumference side as the sum of the emission data and the virtual data goes to the outer circumference side. The number of image data in one clock is the same, and the outermost LED 2 has five clocks, and the amount of data shift is larger than that of the innermost LED 2. For example, assuming that there are 5 pixels of virtual data m in the virtual display area between the LED unit bars 3 adjacent in the circumferential direction, the next data is transferred to the next LED unit bar 3 with 5 clocks and the same data is output about 5 times. To do. Since the amount of blinking data per clock increases from the inner circumference side to the outer circumference side, the LED light emission time per pixel data becomes shorter (faster) from the first stage to the eighth stage. That is, it becomes faster as it approaches the inner peripheral side of the eighth step from the first step on the outermost peripheral side.

  Then, when creating a program, it is possible to calculate the distance on the circumference between the LEDs 2 and 2 of each stage between the LED unit bars 3 and 3 adjacent on the same circumference of the LEDs 2 of each stage of the LED unit bar 3 In addition, since the number of pixels is determined according to the distance in the circumferential direction, the amount of shift on the inner and outer periphery sides is different. The distance of the shift (scroll) in the LED 2 in each stage is set by being controlled by the central controller 6. On the other hand, in the case of Patent Document 1 related to the above prior art, since the adjacent LED unit bars 3 and 3 are arranged in parallel with each other at equal distances, the upper and lower display units are the same at the same speed. Scroll by distance.

  In addition, the relationship with the column data in the intermediate virtual part (virtual display area) between the LED unit bar 3 and the next adjacent LED unit bar 3 in the above embodiment is schematically shown in FIG. In this example, the flow of 4-character bitmap image data “OPEN” composed of 7 × 9 (or 8 × 9) dots in this example, and LED unit bars 3 in the first and ninth columns It is expressed repeatedly. That is, a portion where the dot of the image data and the dot of LED2 overlap is indicated by a black circle, and this black circle LED2 indicates the light emission state. Of one character data composed of nine columns of column data, only two columns of column data are displayed on the adjacent two columns of LED unit bar 3, but the other seven columns of column data in the intermediate virtual part Is hidden and not displayed at all. However, for example, by performing scroll display control at a speed of 10 characters per second, a person watching this can recognize the character as a 7 × 9 (or 8 × 9) bit structure.

  By the way, although one embodiment of the scroll display device has been described above, the embodiment of the display warning lamp 11 using the scroll display device 1 will be described below with reference to the drawings.

  1 is a front view showing an embodiment of a display warning light, FIG. 2 is a rear view of the display warning light of FIG. 1, FIG. 3 is a plan view of the display warning light of FIG. FIG.

  As shown in these drawings, the display warning lamp 11 of this embodiment is a type that is installed on a support base (not shown) and used. For this reason, a flat pedestal 12 is integrally provided at the lower end of the main body 11a of the display warning lamp 11, and set screws 13 for attaching to the support base can be rotated at three locations, two on the front and one on the back of the pedestal 12. Comes with. The main body 11a is formed with arc-shaped protruding portions corresponding to the circular shape of the scroll display device 1 at intermediate positions in the vertical direction of both side surfaces, and the scroll display device 1 is integrally provided on the front and back surfaces of the main body 11a. Further, a plate-like mounting table 14 is integrally provided at the upper end of the main body 11a, and a photovoltaic power generation panel device (hereinafter also referred to as a solar panel) 15 is mounted and fixed integrally on the mounting table 14. In the photovoltaic power generation panel device 15, the center portion of the top surface gradually bulges upward compared to both sides, and the center portion is curved upward in an arc shape when viewed from the front.

  As shown in FIG. 8, a battery 16 is removably accommodated in the main body 11a. In addition to the charge control circuit 22, electronic devices such as a drive circuit (LED display driver) 7 for driving the LED 2 of the scroll display device 1, an image memory 5 for storing image data for scroll display, and a central control device (CPU) ) A microcomputer including 6 is built in the main body 11a. In addition to the indicator lamp 23 that displays the state of charge, the main body 11a is equipped with a changeover switch 18 for switching the scroll display via a display changeover control circuit 24. In addition, a condensing lens 17 (FIGS. 1 and 2) is mounted on the surface of the LED unit bar 3 (LED display unit) 3. This lens 17 can sufficiently increase the brightness of the LED 2 at a low voltage. It is for making it show.

  FIG. 8 is a flowchart showing the entire display warning light of the present invention provided with a photovoltaic power generation panel device. As shown in FIG. 8, the charging control circuit (diode or the like) 22 is controlled so that a current flows only from the solar panel 15 to the battery 16. Further, the voltage generated when the solar panel 15 receives sunlight is not affected by the voltage of the battery 16 by the charge control circuit 22, so the power consumption of the LED 2 of each LED unit bar 3 based on the voltage value of the solar panel 15. In other words, the brightness (illuminance) of the LED 2 is controlled. That is, when the periphery of the display warning light 11 becomes dark (in other words, at night), the voltage value generated in the solar panel 15 decreases, so that the brightness of the LED 2 of the LED display unit 3 is reduced, and conversely the display warning light 11 When the surroundings become bright (in other words, in the daytime), the voltage value increases, so the brightness of LED 2 is increased. As a result, the brightness of the LED 2 is adjusted in accordance with the brightness of the surroundings of the display warning lamp 11, and the scroll display device 1 is always kept in an easy-to-see state, power consumption is suppressed, and energy saving is achieved.

  The control principle of the scroll display described above is further generalized and described as follows. That is, the image memory 5 of the central control unit 6 stores bitmap-format image data of vertical s bits and horizontal w bits, and the virtual display is regarded as a pixel configuration of (s × w) dots. The image data is virtually expanded in the area, and the array pattern of the n LED rows is virtually superposed, and s overlaps the position of each s LED 2 in the row of the LED unit bar 3. Data extraction operation corresponding to extracting dot data from the image memory 5 and supplying it to the driver 7 of the corresponding LED row is performed, and the image data developed in the virtual display area is Based on the data on the outer peripheral side, m is set, and on the inner peripheral side, the same data is duplicated to make the number of data equal to m. Accordingly, since the same data is repeated toward the inner circumference side, the change is reduced. As a result, the LED 2 of each stage in each LED unit bar 3 is actually driven and light is emitted based on the image data. However, the time interval of light emission by the LED 2 of each stage is set at each stage in the virtual display area. The distance by which the light emitting point of the LED 2 scrolls increases toward the outer peripheral side, and looks like FIG.

  As described above, regarding the data in the virtual display area between the LEDs 2 of each stage of the LED unit bar 3 in the radial direction adjacent to each other at equal intervals in the circumferential direction, the number of data (amount) between the first stage (outermost circumference side) From the second stage to the seventh stage (eighth stage), the distance between the second stage and the seventh stage (eighth stage) is extended to be equal to the first stage. In other words, from the second stage to the seventh stage (eighth stage) Since the number of data is less than m, the same data is repeated (duplicated), and the repeated (duplicated) data is gradually increased as it approaches the 7th stage (or 8th stage), and all the basic data By aligning the number m, the number of data from the first stage to the seventh stage (eighth stage) in the virtual display area is made common as m.

  FIG. 9 is a flowchart showing in sequence the operation steps of scroll display by the microcomputer. The read access control procedure of the image memory 5 is as follows. As shown in FIG. 9, the scroll display image data in the image memory 5 is set to m based on the data on the outermost periphery, and the data is moved toward the inner periphery. Since the number of data decreases, the same data is set in duplicate in order to make it equal to the number m of data on the outermost periphery, so that the data changes less as it goes to the inner periphery.

  First, start (step 001) and reset the scroll position point SP to zero. Further, the total number of LED unit bars 3 is n (step 002). Next, the value of the scroll position point SP consisting of all the display data is set (moved) to the read point P which is the read data point (step 003). At this stage, SP = P = 0. Subsequently, the LED display position (position of the LED unit bar 3) as the data writing position, that is, the light point WP is reset to 0 (step 004). At this stage, SP = P = WP = 0. Here, the scroll position point SP represents all positions (points) at which the data of all the virtual display areas between the LED unit bars 3 and the LED unit bars 3 are scrolled, and the lead point P is the data in the image memory 5. The address corresponding to the scroll position point SP is attached to each data in the image memory 5 in step 003. The light point WP represents the position of each LED unit bar 3.

  Write data is written to the write point WP from the data in the image memory 5 (step 005). Data written to the write point WP is set in the shift register (step 006). In this state, 1 is added to the light point WP (step 007).

  Next, it is searched whether or not the data written in the light point WP has reached n which is the total number of LED unit bars 3 (step 008). If NO, the basic display data number m + 1 is added to the lead point P (step 009). As a result, the process proceeds to the step of writing the data of the image memory 5 to the next LED unit bar 3. Steps 005 to 007 described above, that is, write data is written to the write point WP (step 005). Data written to the write point WP is set in the shift register (step 006). 1 is added to the write point WP ( Each step of step 007) is repeated in this order. Next, it is searched whether or not the data written to the light point WP has reached n which is the total number of LED unit bars 3 (step 008). If NO, the basic data numbers m and 1 of the virtual display area are respectively added to the lead point P (step 009), and the process proceeds to the step of writing the data in the image memory 5 to the next LED unit bar 3, Each process is repeated until the data written in the light point WP reaches n which is the total number of LED unit bars 3.

  When the data written in the light point WP reaches n which is the total number of LED unit bars 3 and the search result in step 008 becomes YES, the data of all LED unit bars 3 are latched in the latch circuit, and each LED 2 is connected to the drive circuit. The LED 2 corresponding to the data among all the LED unit bars 3 is caused to emit light (step 010). In the next step, the light emission time of the LED 2, that is, the display time is secured, and the scroll time is adjusted (step 011). Subsequently, 1 is added to the scroll position point SP, and the process proceeds to the next display preparation step (step 012). Then, it is searched whether or not the scroll display is completed (step 013). Then, when the data to be displayed on the LED unit bar 3 does not go to the end, that is, if the search result is NO, the scroll position point SP is set to the read point P that is the read data point (step 003). Returning, the steps from step003 to step013 are repeated. As described above, when the data to be displayed on the LED unit bar 3 reaches the last part and the scroll display is completed, the search result of step 013 becomes YES. Then, the process returns to step 002, and the series of steps (step 002 to step 013) described above are repeated. In this way, all or a plurality of LED unit bars 3 arranged in the circumferential direction simultaneously emit light, and the characters and figures stored in the image memory 5 are displayed by scrolling clockwise or counterclockwise. In the case of the above embodiment, when the interval between the LEDs 2 of the LED unit bar 3 is t, the interval (distance) between the first-stage LEDs 2 arranged on the outermost periphery of the LED unit bar 3 adjacent in the circumferential direction is 5t. However, this interval can be further reduced by increasing the scrolling speed of images such as characters and figures. That is, it can be arbitrarily adjusted at the scrolling speed.

  The embodiment of the display warning lamp of the present invention has been described above. However, the number of columns of the LED unit bar 3 may be, for example, 16 columns or 8 columns, and the LED unit bar 3 is configured. The number of LEDs 2 to be performed may be 16 or 8, for example, and the number of dots of one character of the image data may be 16 × 16 or 8 × 8, for example.

It is a front view which shows one Embodiment of the display warning light of this invention. It is a rear view of the display warning light of FIG. It is a top view of the display warning light of FIG. It is a right view of the display warning light of FIG. It is explanatory drawing which shows the state which removed the circular cover of the front of the display warning light of FIG. It is the schematic which shows the display mode of image data typically, and also displays in the virtual space part which is not actually displayed, and represents the state visible to a person. FIG. 2 is a block diagram of the display warning light of FIG. 1 and a flow diagram of a data transmission system. It is a flowchart which shows the whole display warning lamp of this invention provided with the photovoltaic power generation panel apparatus. It is a flowchart which shows the operation | movement process of the scroll display by a microcomputer (central control apparatus) in order.

Explanation of symbols

1 Scroll Display 2 LED (Light Emitting Element)
3 LED (light emitting element) unit bar 4 Circular display base 5 Image memory 6 Central controller (CPU)
7 Drive circuit (LED driver)
8 Latch circuit (LED data latch)
DESCRIPTION OF SYMBOLS 11 Display warning light 11a Main body 12 Base 13 Set screw 14 Mounting base 15 Solar power generation panel apparatus (solar panel)
16 Battery 17 Condensing lens 18 Changeover switch 22 Charge control circuit 23 Indicator lamp

Claims (3)

An indicator warning light characterized by the following matters (1) to (5).
(1) The n rows of light emitting element unit bars in which S light emitting elements are linearly arranged at a constant interval t are arranged at equal intervals (360 ° / n) in the circumferential direction from the central portion to the outer peripheral portion and along the radial direction. And the interval on the outermost peripheral side of adjacent light emitting element unit bars is set to an integral multiple of the t.
(2) The number of image data to be displayed by the light emitting elements in each light emitting element unit bar includes the outer side data according to the radial distance from the circular center position of the light emitting elements in each stage of the light emitting element unit bar. While increasing step by step compared to the circumferential data,
The data in the virtual display area between the light emitting element unit bars is set to m based on the outermost peripheral side data, and the inner peripheral side is set so that the number of data becomes m by overlapping the same data. .
(3) The image data to be displayed is composed of bitmap format image data including virtual display area data m between the light emitting element unit bars.
(4) The image memory is read-accessed, and the read S column data is written to the light point corresponding to the position of the first light emitting element unit bar, and then sequentially corresponds to the position of each light emitting element unit bar. The column data read from the image memory is written to the write point. Here, each column data is latched and output to the light emitting element of each light emitting element unit bar and displayed. In this state, 1 is added to the scroll point to prepare for the next display, and scroll display is performed by repeating the above procedure.
(5) The image data is distributed to a drive circuit of each light emitting element unit bar via a shift register, and a central control device for controlling the image data as a whole and performing scroll display is provided. The display warning light according to claim 1, characterized by the following matters (6) to (7).
(6) A circular base on which the n rows of the light emitting element unit bars are arranged is provided on both front and rear surfaces of the display warning light main body.
(7) A photovoltaic power generation panel device is provided on the top surface of the display warning light body, a charging battery is built in the display warning light body, and the battery is charged with power generated by the photovoltaic power generation panel device. To do. The display warning light according to claim 2, characterized by the following matters (8).
(8) Power consumption of each light emitting element in the light emitting element unit bar is controlled based on a voltage value generated in the photovoltaic power generation panel device.

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