JP6613048B2 - Altitude display device - Google Patents

Description

  The present invention relates to an altitude display device that serves as an evacuation mark when the occurrence (arrival) of a tsunami is expected due to an earthquake or the like.

  When a disaster such as an earthquake occurs and a tsunami is expected (arrival), it is important to evacuate promptly to high altitude (altitude) in coastal areas. Therefore, it is conceivable that a panel displaying the altitude is installed on a utility pole, a roadside tree, etc., as a refuge mark when a tsunami is expected to occur. Such a panel needs to display (print) the measured altitude on the panel after measuring the altitude of the installation position (the altitude of the ground immediately below the installation position) in advance, which is troublesome. Further, at night or in bad weather, it may be difficult to visually check the panel and confirm the altitude displayed on the panel. On the other hand, it is possible to display the altitude using a phosphorescent paint, but even in this case, if the amount of accumulated light is not sufficient due to bad weather etc., sufficient light emission amount (brightness) and light emission time cannot be obtained. There is a case. Furthermore, when a power outage occurs due to the occurrence of a disaster and the street lights are extinguished, it is more difficult to confirm the altitude displayed on the panel.

  Patent Document 1 compares the height of a tsunami acquired from tsunami information transmitted from a TV station or radio station with the altitude of the current position measured based on the atmospheric pressure of the current position. An evacuation support apparatus that outputs a warning when the altitude is higher than the current position is described. According to the evacuation support apparatus described in Patent Document 1, it is possible to easily determine whether or not it is necessary to evacuate from the current position when a tsunami is expected to occur. However, such an evacuation support apparatus described in Patent Document 1 does not know which direction (direction) should be evacuated (in which direction the altitude is high) when a warning is output. In addition, it is inevitable that the structure for obtaining from tsunami information transmitted from a television station, radio station, etc. is complicated and expensive.

JP 2014-182564 A

  In view of the circumstances as described above, the present invention has been invented to realize a structure of an altitude display device that can be a mark for evacuation from a tsunami at a low cost.

The altitude display device of the present invention includes an altitude acquisition unit, an altitude display unit, and a power feeding unit.
Altitude acquisition unit of this is intended for acquiring the elevation (acquisition), specifically-form, equipped with a pressure sensor. Alternatively, although not within the technical scope of the present invention, the latitude / longitude stored in advance in the memory based on the position information (latitude / longitude) acquired by position information acquisition means such as GPS (Global Positioning System) The altitude can be calculated from the relationship with the altitude (map above sea level).
The elevation display part is attached to a high place (a height of about 1 to 5 m from the ground) such as a utility pole, a streetlight or a fence, or a road tree so that the evacuee can easily confirm by visual inspection, According to the altitude acquired by the altitude acquiring means, the display state of information relating to the altitude is switched. Such an altitude display unit may include, for example , one to a plurality of light emitting elements, or a liquid crystal display or a 7 segment display. In any case, the altitude display section emits light by energization so that the refugee can visually check even when the brightness is insufficient at night or in bad weather.
The power supply means is for supplying power to at least the altitude display section (and also to the altitude acquisition means if necessary), and uses, for example, a battery (primary battery or secondary battery) or a commercial power source. I can do things.
Furthermore, in the altitude display device of the present invention, the altitude acquisition means outputs the altitude calculated based on the atmospheric pressure measured by the atmospheric pressure sensor. The altitude display device of the present invention further includes offset height acquisition means for acquiring an offset height that is the height of the atmospheric pressure sensor from the ground. The altitude display unit switches the display state according to a value obtained by subtracting the offset height acquired by the offset height acquisition means from the altitude calculated based on the atmospheric pressure measured by the atmospheric pressure sensor.

Preferably when performing altitude display device such present invention described above, the pre-Symbol altitude display unit, 1 to comprise a plurality of light emitting elements (LED), according to the altitude acquired by the altitude acquisition means the It is assumed that the light emission mode {color, lighting state (continuous lighting, blinking, extinguishing), etc.} of the light emitting element is switched.

Also, preferably, the pre-Symbol feeding means, composed of a rechargeable secondary battery, solar panels or wind generators, etc., and charging means for charging the secondary battery.
Preferably the case of this embodiment, the apparatus further comprises illuminance acquiring means for acquiring the irradiation degree. Then, when the illuminance acquired by the illuminance acquisition unit is equal to or lower than a predetermined value set in advance, the display state of the altitude display unit is switched according to the altitude acquired by the elevation acquisition unit.

Although not within the technical scope of the present invention, the altitude acquisition means may acquire altitude near the ground (ideally, the ground) . In this case , the altitude display unit is installed above the altitude when the altitude acquisition means acquires the altitude (the height that was located when the altitude was acquired).

Further, preferably when practicing the present invention has a front Symbol altitude acquisition means, the altitude display, accommodates the said feeding means in a single case.

According to the elevation display device of the present invention configured as described above, a structure that can serve as a mark for evacuation from a tsunami can be realized at low cost.
In other words, in the case of the present invention, evacuees from tsunamis have high altitudes while visually checking the altitude display portion attached at a high place (a height of about 1 to 5 m from the ground) even at night or in bad weather. Evacuate quickly to the place. Further, in the case of the present invention, the altitude is acquired by the altitude acquiring means, and the altitude of the installation position is previously set as in the case of installing a panel displaying the altitude in order to switch the altitude display portion according to the acquired altitude. It is not necessary to measure and is easy to install. Further, unlike the evacuation support apparatus described in Patent Document 1 described above, it is not necessary to receive tsunami information transmitted from a television station, a radio station, or the like, and the configuration can be simplified and the cost can be reduced. Furthermore, according to the present invention, the altitude near the ground (ideally, the ground) just below the altitude display section can be displayed more accurately.

Further, if the altitude display section includes one or more light emitting elements and the light emission mode of the light emitting elements is switched according to the altitude acquired by the altitude acquisition means , the altitude display section can be simply configured. And cost can be further reduced.
In addition, if the power supply means is composed of a chargeable / dischargeable secondary battery and a charging means for charging the secondary battery , the altitude can be increased even if a power failure occurs due to a disaster such as an earthquake. It is possible to ensure the function of the display device as a mark for evacuation from the tsunami.
Further, the illuminance acquisition means for acquiring the illuminance is further provided, and the altitude display unit is configured to adjust the altitude acquired by the altitude acquisition means when the illuminance acquired by the illuminance acquisition means is equal to or less than a predetermined value set in advance. If the display state is switched accordingly, the battery capacity (discharge capacity) of the secondary battery as the power supply means can be saved.

Further, if the altitude acquisition means, the altitude display section, and the power feeding means are accommodated in a single case, the handling property can be improved and the installation work can be further facilitated.

The perspective view which shows the elevation display apparatus which concerns on the 1st example of embodiment of this invention in the state seen from diagonally upward. The perspective view shown in the state similarly seen from diagonally downward. The bottom view which shows the state which removed the case main body similarly. Sectional drawing similarly shown in the state which attached the case main body. The block diagram of an altitude display apparatus. The figure similar to FIG. 5 which shows the 1st example of the reference example relevant to this invention.

[First example of embodiment]
1 to 5 show a first example of an embodiment of the present invention. The altitude display device 1 of this example includes a case 2, a power switch 3, a power feeding means 4, an altitude acquisition means 5, an offset adjustment dial 6 that is an offset height acquisition means, a step height adjustment dial 7, An illuminance sensor 8 that is illuminance acquisition means, an altitude display unit 9, and a mounting bracket 10 are provided. In the case 2, the upper opening of the case body 11 is closed by the inner lid 12, and the upper opening of the inner lid 12 is further closed by the solar power generation panel 13 constituting the power feeding means 4. The outer peripheral edge of the upper surface of the power generation panel 13 is held down by a holding frame 15 that is coupled and fixed to the case body 11 with screws 14a and 14a. Of the case main body 11, the window portion 16 provided in the central portion and the portion where the detection portion of the illuminance sensor 8 faces is made of plastic or glass that transmits light (visible light). Thus, the light emitted from the light emitting elements (LEDs) 17a to 17c constituting the altitude display unit 9 provided inside the case body 11 can be visually confirmed from the outside of the case 2, and the illuminance sensor 8, the external illuminance can be confirmed. However, the entire case body 11 may be made of a plastic that transmits light. The inner lid 12 partitions the internal space of the case 2 into a lower space 18 and an upper space 19. An electronic circuit board 20 for mounting electronic components constituting the altitude display device 1 is supported and fixed on the upper surface of the inner lid 12. A method for supporting and fixing the electronic circuit board 20 is not particularly limited. For example, the electronic circuit board 20 can be supported and fixed to the upper surface of the inner lid 12 by screwing.

  The power switch 3 is for switching on / off the power of the altitude display device 1, is constituted by a toggle switch, and is mounted on the electronic circuit board 20. In the case of this example, an oval through hole 22 a is provided in a portion of the bottom plate portion 21 of the case body 11 that is aligned with the operation lever of the power switch 3. The power switch 3 can be turned ON / OFF by inserting a pin portion 24 provided at the tip of the tool 23 into the through hole 22a. In addition, a protruding wall portion is provided on the entire periphery of the upper surface of the bottom plate portion 21 around the through hole 22a so that rainwater or the like does not easily enter the case 2. In the case of this example, the internal space (lower space 18 and upper space 19) of the case 2 and the external space of the case 2 are communicated with each other through the through hole 22a and a through hole 22b described later. The air pressure in the internal space of case 2 is made equal to the atmospheric pressure.

  The power supply means 4 is for supplying electric power to the electronic components constituting the altitude display device 1, and is a chargeable / dischargeable secondary battery 25 and a charging means for charging the secondary battery 25. The photovoltaic power generation panel 13 is provided. Of these, the secondary battery 25 is composed of, for example, a lithium ion battery, a nickel metal hydride battery, or the like, and after adjusting the output voltage to an appropriate value by the voltage adjustment unit 26 mounted on the electronic circuit board 20, Electric power is supplied to the electronic component through an electronic circuit printed on the electronic circuit board 20. The solar power generation panel 13 generates power by irradiating sunlight or the like (converts light energy into electric power). Such a photovoltaic power generation panel 13 is connected to a charging power supply controller 28 mounted on the electronic circuit board 20 via a lead wire 27a, and an output voltage / current is appropriately transmitted by the charging power supply controller 28. After adjusting the value, electric power is supplied to the secondary battery 25 through the electronic circuit, and the secondary battery 25 is charged. In addition, as a charging means for charging the secondary battery 25, a wind power generator, a fuel cell, a commercial power source, or the like is used instead of or in addition to the solar power generation panel 13. You can also do things. In the case of this example, the surface temperature of the secondary battery 25 measured by a temperature sensor 29 such as a thermistor and the output voltage of the secondary battery 25 are connected to a microcomputer mounted on the electronic circuit board 20. It is configured to input to the controller 30 such as an analog circuit. When the surface temperature of the secondary battery 25 is higher than a predetermined temperature (the secondary battery 25 is abnormally heated), or when the output voltage of the secondary battery 25 is higher than a predetermined voltage. Based on the signal from the controller 30, the charging power supply controller 28 stops power supply from the photovoltaic power generation panel 13 to the secondary battery 25, and the secondary battery 25 is broken or overloaded. Prevent charging.

  The altitude acquisition means 5 is for acquiring altitude. In this example, the altitude acquisition means 5 inputs the atmospheric pressure measured by the atmospheric pressure sensor 31 to the controller 30 on the electronic circuit board 20, and this controller The altitude of the installation position of the altitude display device 1 (the installation position of the atmospheric pressure sensor 31) is calculated by 30. The altitude is calculated periodically, for example, while the power switch 3 is turned on (or only while the illuminance measured by the illuminance sensor 8 described later is below a predetermined value). Alternatively, it may be configured to be performed only once immediately after the power switch 3 is turned on, or to output an average value obtained as a result of performing a plurality of times. Further, the temperature (air temperature) of the external space of the case 2 is measured by a temperature sensor provided separately from the temperature sensor 29 for measuring the surface temperature of the secondary battery 25, and the measured value of the atmospheric pressure sensor 31 is obtained. It can also be configured to correct.

  The offset adjustment dial 6 is for setting an offset height, which is a height from the ground of the installation position of the altitude display device 1 (the barometric pressure sensor 31). It is mounted on the circuit board 20. An operator who installs the altitude display device 1 measures the offset height in advance before installing the altitude display device 1 and sets the offset adjustment dial 6 according to the measured offset height (for example, In the example shown in the figure, it is 4). On the outer peripheral surface of the offset adjustment dial 6, a gear-like uneven portion is provided on the entire periphery. Further, a circular through hole 22 b is provided in the bottom plate portion 21 of the case body 11. That is, the pin portion 24 of the tool 23 is inserted into the through-hole 22b, and a gear-like uneven portion provided on the outer peripheral surface of the pin portion 24 over the entire periphery is formed on the outer peripheral surface of the offset adjustment dial 6. The set value of the offset adjustment dial 6 can be changed by rotating the tool 23 in a state of being engaged with the provided uneven portion. A protruding wall portion 32 is provided around the entire circumference of the upper surface of the bottom plate portion 21 around the through hole 22b. This makes it difficult for rainwater or the like to enter the case 2 regardless of the presence of the through hole 22b. The offset adjustment dial 6 can be realized by combining one or a plurality of toggle switches and button switches instead of the dial type shown in the figure. Further, in place of the offset adjustment dial 6 as in the present example, a distance sensor such as a laser type or an ultrasonic type is provided with its detection portion facing downward (facing the ground), and this distance sensor You may make it acquire this offset height by measuring the said offset height.

  The step height adjustment dial 7 is for setting a step height, which is an interval (altitude interval) for switching the display state of the altitude display section 9, and is constituted by a variable resistor or the like, and is configured as the electronic circuit board. 20 is implemented. An operator who installs the altitude display device 1 sets the step height adjustment dial 7 according to the topography of the area where the altitude display device 1 is installed, the height of a tsunami that is expected to reach (for example, In the example shown in the figure, it is 10). Similar to the offset adjustment dial 6, the step height adjustment dial 7 has a pin portion 24 of the tool 23 inserted into a through hole 22 b provided in the bottom plate portion 21, and the entire circumference of the pin portion 24 is formed on the outer peripheral surface of the pin portion 24. The step height adjustment dial is rotated by rotating the tool 23 in a state where the gear-like uneven portion provided over the engagement is engaged with the uneven portion provided on the outer peripheral surface of the step height adjustment dial 7. 7 can be changed.

  The illuminance sensor 8 is for measuring external illuminance, and is constituted by, for example, a photodiode or the like, and is mounted on the electronic circuit board 20. That is, a through hole 33 is provided in a portion of the side surface of the inner lid 12 that faces the detection portion of the illuminance sensor 8, and through the through hole 33 and a portion of the case body 11 that has transparency, The illuminance sensor 8 can measure external illuminance. The upper space 19 in which the illuminance sensor 8 is provided and the lower space 18 in which the altitude display unit 9 is provided are partitioned by the inner lid 12 and are emitted from the altitude display unit 9. It is possible to prevent light from affecting the illuminance sensor 8. Further, as an illuminance acquisition means for acquiring external illuminance, instead of such an illuminance sensor 8, the output of the solar power generation panel 13 is used, or a clock is built in the altitude display device 1, You may comprise so that external illumination intensity may be estimated with the time which a timepiece outputs.

  The altitude display unit 9 includes a plurality of (four in the illustrated example) light emitting units 34 and 34. Each of these light emitting sections 34, 34 has three light emitting elements 17a to 17c (red light emitting element 17a, yellow light emitting element 17b, and blue light emitting element 17c) having different colors (light emitting colors), and each of these light emitting elements. A light emitting unit substrate 35 on which the elements 17a to 17c are mounted and a lead wire 27b for connecting the light emitting unit substrate 35 and the electronic circuit substrate 20 are provided. The light emitting unit substrates 35 and 35 of the light emitting units 34 and 34 are mounted on pedestals 36 and 36 provided at a plurality of locations (four locations in the illustrated example) on the lower surface of the inner lid 12. It supports in the state which inclined in the direction which goes upwards, so that it goes to an outer periphery from a center part. Thereby, the light emitted from each of the light emitting elements 17a to 17c reaches a wide range.

Such altitude display unit 9, the illuminance measured by the illuminance sensor 8 only when it is less than the predetermined value, the altitudes A ₀ measured by the altitude acquisition unit 5, the set in the offset adjustment dial 6 Offset The display state is switched according to the altitude A (= A ₀ −Δh) near the ground (ideally, the ground) just below the installation position of the altitude display device 1 obtained by subtracting the height Δh. Specifically, in the case of this example, the light emitting state of each of the light emitting sections 34, 34, that is, which light emitting element among the light emitting elements 17a to 17c having different colors is switched on is switched. However, each of the light emitting elements 17a to 17c may be a white light emitting element, and each of the light emitting elements 17a to 17c may be configured to be covered with a transparent material having a different color. Alternatively, each of the light emitting units 34 and 34 may be configured by one light emitting element, and the lighting state (continuous lighting, blinking, extinguishing) of the one light emitting element may be switched according to the altitude A. . Further, each of the light-emitting portions 34, 34 is composed of a plurality of light-emitting elements having different colors, and switching which light-emitting element among these light-emitting elements is turned on and lighting of the light-emitting elements that are turned on You can also change the state. In the case of this example, the step height hs, which is the interval for switching the display state, can be adjusted by the step height adjustment dial 7.

  That is, when the altitude A near the ground at the installation position of the altitude display device 1 is equal to or less than the step height hs set by the step height adjustment dial 7 (A ≦ hs), each light emitting element 17a. ˜17c, the red light emitting element 17a is turned on, and the yellow light emitting element 17b and the blue light emitting element 17c are turned off. When the altitude A is larger than the step height hs and not more than twice the step height hs (hs <A ≦ 2hs), the yellow light emitting element 17b is turned on to emit red light. The element 17a and the blue light emitting element 17c are turned off. When the altitude A is larger than twice the step height hs (A> 2hs), the blue light emitting element 17c is turned on, and the red light emitting element 17a and the yellow light emitting element 17b are turned on. Turns off.

  The mounting bracket 10 is configured such that the altitude display device 1 is placed at a high position (a height of about 1 to 5 m from the ground) of a prismatic pillar 37 such as a street lamp or a sign so that the photovoltaic power generation panel 13 is on the upper side. It comprises a pair of support plates 38a and 38b, a pair of long screws 39 and 39, and a wing nut 40 and 40, respectively. One of the support plates 38a and 38b is supported and fixed to the side surface of the case 2 by screws 14b and 14b. And the support | pillar 37 is clamped by both the said support plates 38a and 38b. In this state, the long screws 39, 39 are inserted into the through holes formed in the support plates 38a, 38b, and the wing nuts 40, 40 are inserted into the distal ends of the long screws 39, 39. The altitude display device 1 is supported and fixed at the height of the support column 37 by screwing and further tightening. However, such a mounting bracket 10 can be appropriately changed according to the shape of a portion (a columnar column such as a power pole or a roadside tree or a side surface such as a fence) that supports and fixes the altitude display device 1. .

According to the altitude display device 1 of this example configured as described above, a structure that can serve as a mark for evacuating from a tsunami can be provided at a low cost.
That is, the altitude display device 1 of this example is installed at a predetermined interval (for example, every 10 to 100 m) at a high place on the side of a road such as a coastal area (for example, a high place of a prismatic column 37). For this reason, when a tsunami is expected to occur due to the occurrence of an earthquake or the like, the evacuees check the altitude display part 9 visually at night or in bad weather, that is, at a high altitude, that is, red It is possible to evacuate quickly from the point where the light emitting element 17a is lit to the point where the yellow light emitting element 17b is lit, more preferably to the point where the blue light emitting element 17c is lit.
In the case of this example, the altitude acquisition means 5 automatically acquires the altitude at the installation position of the altitude display device 1 and switches the altitude display section 9 according to the acquired altitude. It is not necessary to measure the altitude of the installation location in advance as in the case of installing the projector, and can be installed easily. In addition, unlike the above-described Patent Document 1, it is not necessary to receive tsunami information transmitted from a television station, a radio station, or the like, and the configuration can be simplified and the cost can be reduced.

  In the case of this example, since the altitude display unit 9 is configured by combining a plurality of light emitting elements 17a to 17c having different colors, the altitude display unit 9 can be configured simply. From this aspect, the cost can be reduced. Such an altitude display unit 9 may be constituted by a liquid crystal panel or a 7-segment display, for example, and the altitude may be displayed numerically. If configured in this manner, the cost is somewhat increased, but the altitude can be reported more accurately.

Further, in the case of this example, the secondary battery 25 is charged by the solar power generation panel 13, and power is supplied to the electronic components constituting the altitude display device 1 by the secondary battery 25. Even when a power outage occurs due to a disaster such as an earthquake, the altitude display device 1 can have a function as a mark for evacuation from a tsunami.
Furthermore, in the case of this example, the display state of the altitude display unit 9 is switched only when the illuminance measured by the illuminance sensor 8 is a predetermined value or less (any one of the light emitting elements 17a to 17c). Therefore, the battery capacity (discharge capacity) of the secondary battery 25 can be saved.

In the case of this example, since the altitude of the installation position of the altitude display device 1 acquired by the altitude acquisition means 5 is corrected by the offset adjustment dial 6, the vicinity of the ground (ideally, the ground ) Can be displayed more accurately.
Moreover, in the case of this example, since each part which comprises the said altitude display apparatus 1 is accommodated in the single case 2, the handleability of this altitude display apparatus 1 can be made favorable. As a result, for example, when an occurrence of a large-scale earthquake is expected and a tsunami is expected, the elevation display device 1 can be easily added.

Although outside the technical scope of the present invention, as the altitude acquisition means for acquiring the elevation of the installation position of the altitude display device, the current positional information acquired by the position information acquisition means such as a G PS (Global Positioning System) Based on the above, the altitude can be obtained from the relationship (altitude map) between the longitude / latitude and the altitude stored in advance in the memory. In this case, the offset height acquisition means for acquiring the offset height which is the height from the ground of the installation position of the altitude display device can be omitted.

[ First example of reference example ]
FIG. 6 shows a first example of a reference example related to the present invention. In the altitude display device 1a of the present reference example, the altitude acquisition means 5a for acquiring the altitude is provided in a terminal 42 that is separate from the apparatus main body 41 provided with the altitude display unit 9 and is present near the ground. The altitude information acquired using the terminal 42 is transmitted from the wireless transmission unit 43 of the terminal 42 to the wireless reception unit 44 of the apparatus main body 41 by short-range wireless communication or the like. In this case, a power source for supplying power to the altitude acquisition means 5a of the terminal 42 is required separately from the secondary battery 25 constituting the power supply means 4. On the other hand, the apparatus main body 41 and the terminal 42 are connected by a cable to perform wired communication and to supply power to the terminal 42 from the secondary battery 25 constituting the power supply means 4. it can. In any case, the altitude information acquired using the terminal 42 is periodically displayed while the power switch 3 is turned on (or only while the illuminance measured by the illuminance sensor 8 is equal to or less than a predetermined value). It may be performed once, or may be performed only once immediately after the power switch 3 is turned on, or an average value of results obtained by performing a plurality of times may be output.

According to the altitude display device 1a of this reference example as described above, the offset height acquisition means for acquiring the offset height that is the height from the ground of the altitude display device can be omitted, and the altitude display device 1a can be omitted. The installation work can be facilitated.
In addition, when implementing the altitude display device 1a of the present reference example, for example, the terminal 42 can be a portable information terminal. That is, with the power switch 3 of the apparatus main body 41 turned on, the portable information terminal acquires the altitude near the ground just below the installation position of the apparatus main body 41, and uses the acquired altitude information as the radio of the apparatus main body 41. Transmitting to the receiver 44. In this case, one terminal 42 (portable information terminal) may be shared among the plurality of altitude display devices 1a (device main body 41).
The configuration and operation of the other parts are the same as in the first example of the embodiment described above.

  The altitude display device of the present invention is installed at predetermined intervals (for example, every 10 to 100 m), for example, on the side of a road in a coastal area where tsunami damage is expected in the event of an earthquake, so that evacuation from the tsunami is possible. Use as a landmark. In addition, the installation of such an altitude display device makes it possible for the local residents to become aware of places where the altitude is high and low, which can lead to an improvement in disaster prevention awareness.

  Moreover, when implementing this invention, you may comprise so that it may display in which direction it should evacuate and the vicinity of a predetermined evacuation center by an altitude display part. Specifically, for example, the direction to evacuate can be indicated by an arrow.

DESCRIPTION OF SYMBOLS 1, 1a Altitude display apparatus 2 Case 3 Power switch 4 Power supply means 5, 5a Altitude acquisition means 6 Offset adjustment dial 7 Step height adjustment dial 8 Illuminance sensor 9 Altitude display part 10 Mounting bracket 11 Case main body 12 Inner lid 13 Solar power generation Panel 14a, 14b Screw 15 Holding frame 16 Window part 17a-17c Light emitting element 18 Lower space 19 Upper space 20 Electronic circuit board 21 Bottom plate part 22a, 22b Through-hole 23 Tool 24 Pin part 25 Secondary battery 26 Voltage adjustment part 27a, 27b Lead wire 28 Charging power supply controller 29 Temperature sensor 30 Controller 31 Atmospheric pressure sensor 32 Projection wall portion 33 Through hole 34 Light emitting portion 35 Light emitting portion substrate 36 Base 37 Support column 38a, 38b Support plate 39 Long screw 40 Wing nut 41 Device body 42 terminal 43 wireless transmission unit 44 wireless reception unit

Claims (5)

Altitude acquisition means for acquiring altitude,
An altitude display unit that is attached to a high place and switches the display state of information about the altitude according to the altitude acquired by the altitude acquisition means,
Power supply means for supplying power to at least the altitude display section;
Equipped with a,
The altitude acquisition means has an atmospheric pressure sensor for measuring atmospheric pressure, and outputs an altitude calculated based on the atmospheric pressure measured by the atmospheric pressure sensor.
An offset height acquisition means for acquiring an offset height that is a height from the ground of the atmospheric pressure sensor;
The altitude display unit switches the display state according to a value obtained by subtracting the offset height acquired by the offset height acquisition means from the altitude calculated based on the atmospheric pressure measured by the atmospheric pressure sensor. apparatus. The altitude display unit includes one to a plurality of light emitting elements, and switches the light emission mode of the light emitting elements according to the altitude acquired by the altitude acquisition means.
The elevation display device according to claim 1. The power supply means is composed of a chargeable / dischargeable secondary battery and a charging means for charging the secondary battery.
The altitude display device according to any one of claims 1 and 2. It further comprises illuminance acquisition means for acquiring illuminance,
When the illuminance acquired by the illuminance acquisition unit is equal to or lower than a predetermined value set in advance, the elevation display unit switches the display state according to the altitude acquired by the elevation acquisition unit.
The altitude display device according to any one of claims 1 to 3. The altitude acquisition means, the altitude display section, and the power feeding means are housed in a single case.
The altitude display device according to any one of claims 1 to 4 .

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