JP2012016086A - Outdoor display system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an outdoor display system in which a display device receiving power supply from a solar battery can operate smoothly even in rain.SOLUTION: An outdoor display system 100 comprises: a solar battery 1; a storage battery 2 to store power; a display device 3 to display contents; and a controller 7 to supply the power obtained by the solar battery 1 to the display device 3 or the storage battery 2. The controller 7 changes a ratio of the power supplied to the display device 3 and the power stored by the storage battery 2 depending on an atmospheric pressure or weather prediction information at the time.

Description

  The present invention relates to an outdoor display system. In particular, the outdoor display system is equipped with a power generation device such as a solar battery and is suitable for use at a bus stop or other transportation stop.

In recent years, an advertising medium called digital signage that displays video and information on a flat display or the like using digital technology for display and communication has appeared. These signage terminals (advertising media) are also used at public transportation stops such as bus stops (Patent Document 1).
JP 2009-294284 A (FIG. 3)

  Naturally, it is necessary to supply electric power to drive the signage terminal. When installing outdoors, since it is necessary to receive electric power supply from an electric power line, electrical work is needed in addition to installation work. This is one of the obstacles to the spread of signage terminals.

  Therefore, it is conceivable that power supply from the power line is unnecessary by integrating solar cells, storage batteries, and the like into the signage terminal. However, since the solar cell cannot generate power at night, it is necessary to supply power from the storage battery to the signage terminal. Furthermore, in the case of rain, it is necessary to supply power from the storage battery. In this case, the power stored in the storage battery may be expelled.

  An aspect of the outdoor display system of the present invention includes a solar cell, a power storage device that stores power, a display device that displays content, and a controller device that supplies power obtained by the solar cell to the display device or the power storage device. The controller device changes the ratio of the power supplied to the display device and the power stored in the power storage device according to the current atmospheric pressure.

  An outdoor display system according to another aspect includes a solar cell, a power storage device that stores power, a display device that displays content, a controller device that supplies power obtained by the solar cell to the display device or the power storage device, And the controller device changes the ratio of the power supplied to the display device and the power stored in the power storage device according to the current weather forecast information.

  ADVANTAGE OF THE INVENTION According to this invention, the display apparatus which receives electric power supply from a solar cell comes to be able to operate | move smoothly even in rainy weather.

(First embodiment)
FIG. 1 is an external view of an outdoor display system 10 according to the first embodiment of the present invention.

  The outdoor display system 10 includes a solar cell 1, a storage battery 2, a display device 3, a poster 4, a bench 5, and a roof 6. A human sensor 33 and a camera sensor 34 are provided on the front side of the display device 3, and a barometric pressure sensor 41 is provided on the back side (not shown).

  The solar cell 1 generates power by photoelectrically converting received sunlight. Here, a solar cell module composed of a solar cell panel or the like and an inverter are generically named. The storage battery 2 is, for example, a lithium ion battery (battery pack).

  The display device 3 is an LCD display including a display panel 32 (described later) such as a liquid crystal panel (LCD). The display device 3 displays content received from an external content server or broadcast station. Further, in view of being installed at a bus stop, the display device 3 displays a bus route map, a bus operation status (for example, an operation status such as the arrival of a bus at the adjacent bus stop), and the like.

  In the present embodiment, the display device 3 includes an antenna (included in a transmission / reception unit 35 described later), and can receive content wirelessly.

  In this way, the display device 3 is driven by the electricity generated by the solar cell 1 and does not receive power supply from the power line. The display device 3 operates so-called off-grid. Therefore, electric work for drawing power from the power line is unnecessary. In addition, since the content can be received wirelessly, it is not necessary to install a wire for connecting to a network (LAN or WAN). As described above, according to the outdoor display system 10 of the present embodiment, the burden of installation work can be greatly reduced, which greatly contributes to the spread of signage terminals outdoors.

  A human sensor 33 and a camera sensor 34 are arranged on the surface of the display device 3 (below the image display portion).

  The human sensor 33 is for detecting the presence or absence of a person at the bus stop, and uses, for example, an infrared sensor. For example, when the human sensor 33 determines that there is no person, the display device 3 reduces the illuminance of the backlight 39 or turns off the backlight 39 itself. Thereby, reduction of electric power is aimed at.

  The camera sensor 34 determines the gender of the person at the bus stop by performing image processing on the captured image. For example, if it is determined that the person at the bus stop is a woman, a cosmetic advertisement is displayed on the display unit, and if it is determined that the person is a man, a beer advertisement is displayed on the display unit.

  An atmospheric pressure sensor 41 is disposed on the back side of the display device 3. The atmospheric pressure sensor 41 is for detecting the external atmospheric pressure.

  The poster 4 has a light-transmitting advertising film on which an advertisement is printed, and an incandescent lamp that irradiates the film from the inside (the side opposite to the display surface). The poster 4 is the same as the display device 3 in that the advertisement is displayed. However, the display content of the display device 3 is changed as a moving image according to the content content received by the receiving unit. Displays a printed matter, which is basically a still image and the display content does not change.

  The bench 5 is for a person waiting for the bus to sit down and is arranged on the front side of the display device 3. When the display device 3 is arranged so that the back surface is on the roadway side, the person sitting on the bench 5 waits for the bus while watching the advertising content displayed on the display device 3. On the contrary, when the display device 3 is arranged so that the display surface faces the roadway, the passenger seat of the passenger car, the passenger on the bus, or the person on the sidewalk on the opposite side can view the advertisement content. . Of course, even a person sitting on the bench 5 can watch the advertising content if he sits with his back on the roadway.

  The roof 6 is disposed above the display device 3 and acts as a person waiting for the bus, or as a sunshade and rain shield for the display device 3. Moreover, since the solar cell 1 and the storage battery 2 are disposed on the roof 6, the roof 6 also functions as an installation base. In the present embodiment, the light receiving surface of the solar cell 1 is arranged with a slight inclination with respect to the roof 6 in consideration of the direction in which sunlight is irradiated. The storage battery 2 is disposed between the solar battery 1 and the roof 6. That is, the solar cell 1 is deployed using the space on the triangular prism generated by the inclination of the solar cell 1 with respect to the roof 6.

  Although not shown in FIG. 1, the outdoor display system 10 also includes a controller 7. The controller 7 supplies the power generated by the solar cell 1 to the display device 3 and the storage battery 2. The operation of the controller 7 will be described in detail later.

  FIG. 2 is a block diagram illustrating a configuration of the outdoor display system 10. Although the description partially overlaps with FIG. 1, the outdoor display system 10 includes a solar cell 1, a storage battery 2, a display device 3, and a controller 7. The display device 3 includes a control unit 31, a display panel 32, a human sensor 33, a camera sensor 34, a transmission / reception unit 35, a storage unit 36, a display control unit 37, a power supply circuit 38, a backlight 39, and a touch panel 40.

  The electric power generated by the solar cell 1 is sent to the controller 7. In principle, the controller 7 supplies most of the power generated by the solar cell 1 to the display device 3 as it is. Then, surplus power (differential power between the power generated by the solar cell 1 and the power consumed by the display device 3) is supplied to the storage battery 2. Further, the controller 7 performs control so that power is supplied from the storage battery 2 to the display device 3 at night or in rainy weather. That is, the electric power stored in the storage battery 2 is transmitted to the display device 3 via the controller 7. The configuration of the controller 7 will be described in detail later.

  As described above, the display device 3 according to the present embodiment does not receive power supply from the power line and operates in an off-grid manner. That is, all the electric power necessary for driving the display device 3 is provided by the power generation by the solar cell 1. Therefore, the specifications of the solar cell 1 are selected and designed in consideration of the power consumption of the display device 3. Specifically, first, it is necessary to determine the power generation amount necessary for the solar cell 1 in consideration of the power consumption of the display device 3. Next, it is necessary to determine the size (surface area) of the solar cell in consideration of the power generation efficiency of the solar cell. In addition, it is necessary to determine the capacity of the storage battery 2 assuming a case where no sunlight is irradiated, such as at night or in the rain.

  The control unit 31 controls each unit (display panel 32 to touch panel 40) of the display device 3 and collects status information of each unit. Moreover, each part is controlled according to the collected state information. Further, a command from the controller 7 (for example, an energy saving operation command for the display device 3) is also input to the control unit 31. The control unit 31 is configured by a CPU.

  The display panel 32 is a part that actually displays an image. In the display device 3 of the present embodiment, a liquid crystal display panel is used. In the liquid crystal display panel, the liquid crystal corresponding to each pixel of the panel is driven on / off (or in an intermediate state) according to the content of the image to be displayed.

  As described above, the human sensor 33 is for detecting the presence or absence of a person at the bus stop. As described above, the camera sensor 34 is provided for the purpose of determining the gender of the person at the bus stop. The human sensor 33 and the camera sensor 34 are connected to the control unit 31, and detection results from these sensors are input to the control unit 31.

  The transmission / reception unit 35 includes an antenna that receives a signal transmitted from an external content server (for example, an ASP server, a personal computer, etc.) or a broadcasting station by wireless communication (for example, a system such as WiMAX, IEEE802.11b / g), A signal processing unit that performs demodulation processing or the like on the signal received by the antenna is provided. Here, the received signal includes advertising content, a control signal of the outdoor display system 10 transmitted from a management company of the outdoor display system 10, and surrounding weather prediction information transmitted from a weather prediction company. If the advertising content is, for example, an MPEG2-TS format signal that is modulated and transmitted by the OFDM method, the transmission / reception unit 35 performs OFDM demodulation and extracts the MPEG2-TS signal. The extracted MPEG2-TS signal is output to the storage unit 36.

  Moreover, the transmission / reception part 35 can transmit a signal to the exterior by radio | wireless communication via a transmission antenna. The signal to be transmitted includes, for example, operation information of the outdoor display system 10, failure occurrence information, and the like, and these pieces of information are transmitted to a management company of the outdoor display system 10. Further, when the content displayed on the display panel 32 is interactive (bidirectional) content, a user input result from the touch panel 40 is transmitted to the content server via the transmission / reception unit 35.

  Of the signals received by the transmission / reception unit 35, the control signal of the outdoor display system 10 and the surrounding weather prediction information are transmitted to the controller 7 via the control unit 31 and the control unit 73. The controller 7 controls the outdoor display system 10 using these signals and information. This will be described in detail later.

  The accumulation unit 36 stores the MPEG2-TS signal extracted by the transmission / reception unit 35. That is, the content transmitted from the content server or broadcasting station is stored. When the content is real-time content (when the received content is displayed on the display panel 32 immediately), the storage unit 36 functions as a buffer memory. When the content is content that is displayed in response to a user operation or content that is displayed based on a preset time schedule, the storage unit 36 functions as a storage medium.

  The display control unit 37 performs display control on the display panel 32. Specifically, the liquid crystal corresponding to each pixel of the display panel 32 (liquid crystal display panel) is modulated according to the content to be displayed. Since the display control unit 37 requires high-speed processing, the display control unit 37 is realized by a dedicated hardware circuit provided separately from the control unit 31 configured by the CPU.

  The power supply circuit 38 supplies power to each part of the display device 3. In view of the fact that the power consumption of the display panel 32 and the backlight 39 is larger than that of other portions, the power supply circuit 38 supplies power only to the display panel 32 and the backlight 39 in FIG. It is described as follows. However, in practice, the power supply circuit 38 also supplies power to the transmission / reception unit 35, the storage unit 36, the display control unit 37, the human sensor 33, the camera sensor 34, the touch panel 40, and the like.

  The backlight 39 irradiates the display panel 32 with white light. As the backlight 39, for example, a cold cathode fluorescent lamp (CCFL) or an LED light source is used. Since the display device 3 of the present embodiment is used off-grid, low power consumption is desired. Therefore, it is preferable to use an LED light source.

  The touch panel 40 is a transparent capacitive touch sensor disposed on the front side of the display panel 32. The touch panel 40 receives input from the user. For example, when the display panel 32 displays a button image for the user to select three, when the user touches a position corresponding to the button image on the touch panel 40, it is considered that the user has made an input.

  The atmospheric pressure sensor 41 detects the atmospheric pressure as described above. The atmospheric pressure value detected by the atmospheric pressure sensor 41 is output to the control unit 31. Further, the atmospheric pressure value is sent to the controller 7. Based on this atmospheric pressure value, the controller 7 changes the ratio of the ratio supplied to the display device 3 and the ratio stored in the storage battery 2. Specifically, when the current atmospheric pressure is low, the ratio of the proportion of electricity stored in the storage battery 2 is increased. If the current barometric pressure is low, there is a high possibility that it will turn to rain later. In rainy weather, it is necessary to supply power from the storage battery 2 to the display device 3. In this case, in order to prevent the power stored in the storage battery 2 from being driven out, if the current atmospheric pressure is low, The ratio of the ratio for storing electricity is increased.

  FIG. 3 is a block diagram showing the configuration of the controller 7. The controller 7 includes a switching unit 71, a control unit 72, and a switch 73. The switching unit 71 is for switching whether the electric power generated by the solar battery 1 is output to the display device 3 or the storage battery 2. The switching unit 71 is controlled by the control unit 72 as described later. The switching unit 71 may have a switch configuration that alternatively determines an output destination. Or the structure which can change the ratio output to the display apparatus 3 and the ratio output to the storage battery 2 (for example, the structure which can be varied, such as outputting 50% at a time, or outputting 100% to one side) may be sufficient.

  The control unit 72 performs various controls inside the controller 7. In addition, control information from the display device 3 (for example, information on an atmospheric pressure value measured by the atmospheric pressure sensor 41) is received, or a control signal is transmitted to the display device 3.

  The switch 73 is for switching whether to output the power stored in the storage battery 2 to the display device 3 or not. The switch 73 is also controlled by the control unit 72 as will be described later.

  FIG. 4 is a flowchart illustrating an example of processing by the controller 7.

  In step S <b> 1, the control unit 72 confirms information on the atmospheric pressure value A measured by the atmospheric pressure sensor 41.

In the subsequent step S2, it is determined whether or not the atmospheric pressure value A is less than a predetermined atmospheric pressure _ATH . When the atmospheric pressure value A is less than the predetermined atmospheric pressure _ATH (when it is determined as “yes” in step S2), the energy saving mode is set for the display device 3 under the assumption that the atmospheric pressure is low and the possibility of raining later is high. Send a command to drive at. Moreover, the control part 72 controls the switching part 71 at this time, and changes the ratio output to the storage battery 2 among the outputs from the solar cell 1 to a higher value.

On the other hand, if it is greater than or equal to _ATH (when determined to be no in step S2), the display device 3 is operated in the normal mode under the assumption that the atmospheric pressure is sufficiently high and the possibility of rain is low. Send a command. At this time, the control unit 72 controls the switching unit 71 to change the ratio of the output from the solar battery 1 to be output to the storage battery 2 lower or to output all to the display device 3 side. Let

  In addition, when the operation in the energy saving mode is instructed, the display device 3 performs control such that the luminance of the backlight 39 is set to a value lower than normal, for example.

  Thus, the controller 7 predicts the possibility of rain and performs power saving control on the display device 3.

  Although not shown in the flowchart of FIG. 4, when no power generation is performed by the solar battery 1 such as rainy weather, cloudy weather, or nighttime, the control unit 72 controls the switch 73 to be stored in the storage battery 2. The display device 3 is controlled so that the power is supplied to the display device 3. In addition, when the solar cell 1 is generating electric power, such as when it is fine, the control unit 72 controls the switch 73 so that the electric power stored in the storage battery 2 is not supplied to the display device 3.

  In the above, the example of this invention was demonstrated using the Example. It should be noted that these embodiments should not be construed as limiting the invention described in the scope of claims or reducing the scope, and the configuration of each part of the present invention is not limited to the above-described embodiments. Of course, various modifications are possible within the technical scope described in the scope.

  For example, the atmospheric pressure information measured by the atmospheric pressure sensor 41 may be transmitted to the controller 7 as needed, or may be transmitted to the controller 7 only when the atmospheric pressure becomes lower than a predetermined value.

  In the above embodiment, the human sensor 33 and the camera sensor 34 are provided. However, the camera sensor 34 may also function as the human sensor 33. That is, instead of detecting the presence or absence of a person using infrared rays, the presence or absence of a person may be detected from an image captured by a camera.

  In addition, although the liquid crystal display panel was demonstrated to the example as an example of the display part of the display apparatus 3, it replaced with this and a plasma panel and organic EL. Also, electronic paper, CRT, or advertising film may be used.

  In the above embodiment, the atmospheric pressure sensor 41 is disposed on the back side of the display device 3, but may be disposed inside the housing of the display device 3. Further, the atmospheric pressure sensor 41 may be provided as a separate body from the display device 3.

  Further, the controller 7 determines the ratio of the power supplied to the display device 3 and the power stored in the storage battery 2 according to the detection result of the atmospheric pressure by the atmospheric pressure sensor 41. Instead of this, the controller 7 may perform the above determination based on atmospheric pressure information transmitted from the outside (received by the transmission / reception unit 71).

  Moreover, the controller 7 may perform the said determination based on the weather prediction information transmitted from the outside. For example, if the weather forecast is a forecast for rainy weather, the configuration may be such that the ratio of the power stored in the storage battery 2 is increased.

  Moreover, in the said Example, the transmission / reception part 35 of the display apparatus 3 receives the control signal of the outdoor display system 10 transmitted from the management provider of the outdoor display system 10, the surrounding weather prediction information transmitted from a weather prediction company, etc. However, a configuration in which a transmission / reception unit is provided on the controller 7 side may also be used. In this case, the control signal and the weather prediction information may be received on the controller 7 side, and the display device 3 side may be configured to receive only the advertising content.

1 is an external view of an outdoor display system 10. FIG. 1 is a block diagram showing a configuration of an outdoor display system 10. FIG. 3 is a block diagram showing a configuration of a controller 7. FIG. 4 is a flowchart illustrating an example of processing by a controller 7;

DESCRIPTION OF SYMBOLS 1 Solar cell 2 Storage battery 3 Display apparatus 4 Poster 5 Bench 6 Roof 7 Controller 33 Human sensor 34 Camera sensor 41 Pressure sensor

Claims (2)

Solar cells,
A power storage device for storing electric power;
A display device for displaying content;
A controller device for supplying power obtained by the solar cell to a display device or a power storage device,
An outdoor display system, wherein the controller device changes a ratio of electric power supplied to the display device and electric power stored in the electric storage device according to the current atmospheric pressure.
Solar cells,
A power storage device for storing electric power;
A display device for displaying content;
A controller device for supplying power obtained by the solar cell to a display device or a power storage device,
An outdoor display system, wherein the controller device changes a ratio of electric power supplied to the display device and electric power stored in the electric storage device according to the current weather prediction information.