JPH11348874A - Lighted buoy, remote inspection controller therefor, remote control transceiver therefor, and remote inspection control system therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate maintenance and to take quick actions against an accident or failure. SOLUTION: This lighted buoy is provided with a floating body 10 involving a heavy bob 4 below it and a lamp 12 above it. The buoy has a remote inspection controller which is provided with a charging and discharging control means controlling charging condition of a solar battery 17 mounted for charging a storage battery 15 serving as a power supply for the lamp and discharging condition of the storage battery 15, a measuring means which measures respective function of the lamp, the storage battery, and the solar battery, a receiving part which receives infrared rays of remote control signal 1a from a remote control transceiver 19, an arithmetic processing means which processes the outputted signal from the measuring means based on the command of the remote control signal received at the receiving part, an indicator which indicates a charging and discharging condition of the storage battery processed by the arithmetic processing means, and a transmitting part which transmits the data 1b superimposed on the infrared rays of the lamp, the storage battery, and the solar battery. A hoisting lug is fitted on the top part.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light buoy, a remote control device, a remote control transceiver, and a remote control system. More specifically, the light buoy emits light so as to be effective even at night. A light buoy equipped with a remote inspection control device capable of remotely controlling maintenance and inspection by an infrared remote control transmitter / receiver. And a remote inspection control system for the same.

[0002]

2. Description of the Related Art FIG. 7 is a view showing an example of a conventional light buoy. In the figure, a daylight 2a, a lamp 2b, and a radar reflector 2 are provided above a floating body 1 formed as a hollow body made of a steel plate.
c, a functional part 2 including a solar cell 2d and the like are provided on a base 3 fixed to the floating body 1, and a cylindrical weight supporting cylinder 4a fixed to a center of a lower surface of the floating body 1 by a fixing member 4b or the like. Is provided, and a weight 4 for maintaining stability is attached to a lower portion thereof. At the bottom of the floating body 1, a mooring portion 1a is provided. The mooring portion 1a and the connecting portion 6 are connected by ropes 5a and 5b such as chains, and an anchor or a deadweight 7 is connected to a rope 5c connected to the connecting portion 6. The light buoy is kept at a predetermined position. The floating body 1 is provided with a storage battery 8 serving as a power source of the lamp 2b, and the storage battery 8 is charged by a voltage from the solar cell 2d.

[0003] As is well known, a light buoy is an important sign for securing a navigable water area or a route of a ship at night, and maintenance and inspection of each electric system of a lamp 2b, a solar battery 2d, and a storage battery 8 are required. , Which is regularly implemented. By maintaining these devices in normal operation, it is ensured that the safety of the navigation of the ship is ensured.

[0004]

The light buoy is a structure floating on the sea, and is constantly under sway due to the waves, and is subjected to very complicated motion due to the addition of a ship's running waves. I always do. Under such conditions, the presence or absence of damage to the light buoy and the maintenance and inspection of its electrical system are performed by inspectors trained in certain maintenance and inspection. However, safely transferring the buoy from the vessel to the light buoy for maintenance and inspection requires skill and danger. Further, depending on the sea conditions in the sea area where the light buoy is installed, there may be a case where the maintenance and inspection must be stopped from the viewpoint of safety even if the light buoy is approached for the maintenance and inspection. Further, there is a possibility that a situation may occur in which the damaged light buoy must be left in the sea area without maintenance.

[0005] In addition, it is difficult for a small light buoy to move from a ship to the light buoy and perform maintenance and inspection.
Usually, light buoys are pulled up to the ship for maintenance and inspection.
However, conventionally, a suspension ring 1b for raising the light buoy is provided on the upper surface of the floating body of the light buoy, and it is relatively difficult to hook the suspension ring 1b at a position close to the sea surface with the hanger of the ship's clen. Work. The maintenance and inspection of the light buoy requires the hook to be hooked on the suspension ring 1b of the light buoy, the lifting of the anchor and the sinking weight, the lifting of the light buoy on the ship, and the maintenance and inspection work. There are drawbacks.

The conventional light buoy is a hollow body made of a steel plate. In recent years, the number of ship collisions has increased dramatically.
It loses its function as a sign by turning off the light and causing other ship accidents. In particular, if the lamp fails, the risk of the ship colliding with the light buoy at night increases, and it is important to perform maintenance and inspection of the electric system of the light buoy in advance. In addition, it is important that the light buoy has a structure that does not easily sink even if a ship collides, and that the maintenance and inspection of the electric system is easy.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and has a light buoy having a lifting tool or the like which can be easily maintained and inspected and can easily cope with an accident or a failure.
It is an object of the present invention to provide a remote inspection control device, a remote control transceiver, and a remote inspection control system.

[0008]

SUMMARY OF THE INVENTION The present invention has achieved the above-mentioned objects, and the invention of claim 1 is a lamp having a weight at a lower portion of a floating body and a lamp at an upper portion thereof. In the buoy, the light buoy is provided with a storage battery as a power source of the lamp and a solar cell for charging the storage battery, and a charge / discharge for controlling a state of charge of the storage battery by the solar cell and a state of discharge of the storage battery. Control means, measuring means for measuring the functions of the lamp, storage battery and solar cell, at least one receiving section for receiving a remote control signal by infrared rays from a remote control transceiver, and receiving the remote control signal to the receiving section And a signal processing means for processing the output signal from the measuring means in accordance with the instruction of the remote control signal, a display for displaying the charge / discharge state of the storage battery by processing the processing means. Based on the remote control signal, the lamp device, a lighting buoy characterized in that it comprises a remote inspection control device and at least one transmission unit transmits the superimposed data of the storage battery and solar cell in infrared. In this configuration, when performing maintenance and inspection of the light buoy, a remote control transmitter / receiver transmits a remote control signal by infrared rays to a remote inspection control device to control the lamp, the storage battery that is the voltage source thereof, and the solar battery for charging the storage battery. It has a function to receive the function at a remote location by infrared data and check the electric system of the light buoy.

According to a second aspect of the present invention, in the light buoy according to the first aspect, the floating body is an annular body in which at least two segments each including a porous member as a filler are connected to each other. It is a light buoy. In this configuration, even if a part of the floating body is damaged, it has a mechanism that can be repaired only by replacing the part.

According to a third aspect of the present invention, the state of charge of the storage battery, which is the power supply of the lamp provided on the light buoy, is controlled by the solar cell, and the state of discharge of the storage battery by energizing the lamp is controlled. Charge / discharge control means, lighting means of the lamp, measurement means for measuring the output voltage of the storage battery, output current of the solar cell, and the like, and at least one of receiving a remote control signal by infrared rays from a remote control transceiver A receiving unit, an arithmetic processing unit that performs signal processing on an output signal from the measuring unit in accordance with a command of the remote control signal, at least one transmitting unit that transmits data of the lamp, the storage battery, and the solar cell, and the storage battery And a display for displaying the state of charge of the light buoy. In this configuration, when performing maintenance and inspection of the light buoy, the remote inspection control device receives an infrared remote control signal from the remote control transceiver and performs signal processing by the CPU, and based on the remote control signal, the lamp and its voltage source. Each function of a storage battery and a solar battery for charging the storage battery can be transmitted by infrared rays.

According to a fourth aspect of the present invention, there is provided a light buoy remote inspection control device according to any one of the first to third aspects,
A transmitting unit for transmitting a remote control signal by infrared rays, at least one receiving unit for receiving data from the remote inspection control device, an arithmetic processing unit for performing signal processing on the data, and displaying an arithmetic result by the arithmetic processing unit An external storage means for storing the calculation result; a key input means for generating a command for remotely controlling the remote inspection control device and a command for causing the data to be signal-processed by the calculation processing means; And a remote control transmitter / receiver for a light buoy. In this configuration, a remote control signal by infrared can be transmitted to the remote inspection control device mounted on the light buoy, and data from the remote inspection control device is received by the remote control transceiver, and data is transmitted from the remote inspection control device. Has a function of reading out, performing arithmetic processing by a CPU, and storing the result in a memory card or the like.

According to a fifth aspect of the present invention, there is provided a light buoy remote inspection control device according to any one of the first, second, and third aspects,
By the remote control transceiver for light buoy according to claim 4,
A remote inspection control system for a light buoy, wherein the function of the light buoy is remotely inspected by infrared data transmission. In this configuration, the remote control transmitter / receiver for the light buoy has a function of storing the data in an external storage device.
By calculating each data, the average value etc. is calculated,
It has a function of displaying the calculation result on a display and storing the calculation result in a memory card or the like.

Further, the invention of claim 6 provides the invention according to claims 1 to 5
The light buoy according to any one of the above, further comprising at least one rod-shaped member provided with a suspension ring for raising the light buoy for maintenance and inspection. In this configuration, a suspension ring for raising the light buoy is provided above the light buoy, so if a defect is confirmed by remote inspection control, the inspector does not move onto the light buoy and It is possible to fix the light buoy immediately by hooking the lifting device of the crane on the suspension ring from the ship and pulling it up on the ship without being affected by the marine conditions.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. An embodiment of the present invention includes a light buoy, a light buoy remote inspection control device mounted on the light buoy, a light buoy remote control transceiver for remotely operating the remote inspection control device, and a remote inspection control device and a remote control. The present invention also includes a form relating to a remote inspection control system for a light buoy comprising a transceiver.

FIG. 1 shows an embodiment of the present invention. FIG. 1 (a) is a side view of a light buoy, FIG. 1 (b) is a plan view thereof, and FIG. 1 (c) is a remote control transceiver for a light buoy. FIG.
FIG. 2 shows a remote control system for light buoys using the remote inspection control device for light buoys of FIG. 1 and a remote control transceiver.
A block diagram of the electric system is shown.

First, the light buoy will be described with reference to FIG. In the same figure, the light buoy has a cylindrical weight supporting tube 4a inserted into the center of a floating body 10, and the floating body 10 and the weight supporting cylinder 4a are fixed by fixing members 4b and 4c.
A weight 4 for stably maintaining the light buoy is attached to the lower part of the slab, and an anchor or a sinking weight 7 is connected to a cable 9 such as a chain to a connecting portion 4d provided at the lowermost end thereof, and the weight is supported. Cylinder 4a
A lamp 12 is provided at the uppermost end of the floating body 10, and a day mark 13 is provided on the weight support tube 4 a above the floating body 10.
The display board 14 is provided on the upper part of. Further, the head 11 is supported on the upper end of the weight supporting cylinder 4a, and the solar cell 1
An annular support member 16 on which the device 7 can be placed is provided.

The floating body 10 has an annular structure in which two segments each formed by filling a porous member such as urethane foam into an annular member are connected to each other by bolts and nuts. The annular member itself is a hollow structure made of, for example, FRP or ABS resin. With such a structure, even if the ship collides with the floating body 10, the structure has elasticity, is strong in impact, and even if broken, seawater immediately flows in and does not sink into the sea. In addition, as an example, the light buoy is provided with a suspension ring 4e for collecting the light buoy in the upper weight support cylinder 4a.

On the other hand, on the upper part of the dayboard 13, a remote control device 18 for waterproofing light buoys is provided.
The storage battery 15 as a power source of the lamp 12 and the solar battery 17 for charging the storage battery 15 are electrically connected to the light buoy remote inspection control device 18 by cables. The light buoy remote inspection control device 18 is provided on its outer surface with a sensor of a transmitting / receiving unit, a light emitting diode of a light emitting display unit, and the like. Remote control transmitter / receiver 19 shown in FIG.
From the remote control signal Ia by infrared rays from
The data signal Ib by infrared is transmitted to the remote control transceiver 19. Thus, the remote control signal Ia by infrared light
Remote control device for light buoy by remote control
8, the maintenance of the electric system of the light buoy is performed.

Next, a remote inspection control device for a light buoy, a remote control transceiver for the same, and a remote inspection control system for the same according to the present embodiment will be described with reference to the block diagram of FIG. As shown in the figure, the light buoy remote inspection control system of the present embodiment includes a light buoy remote inspection control device 18 and a remote control transmitter / receiver 19, and transmits data by infrared rays without transferring to the light buoy. Thus, the electric system of the light buoy can be inspected from the ship by remote control.

First, the light buoy remote inspection control device 18 will be described. Light buoy for remote inspection control device 18 is composed of a CPU (central processing unit) 18A an arithmetic processing unit or a control unit or the like, the transmission unit 18 ₂ which comprises a receiving portion 18 ₁ and the light emitting device including a light-receiving element A transmitting and receiving unit 18B;
A charge / discharge control monitoring unit 18C and an output detected by the charge / discharge control monitoring unit 18C are signal-processed by an A / D converter.
A and a measuring unit 18D to send the storage battery voltage of the storage battery 15 to C
It is composed of a light-emitting display unit 18E that performs arithmetic processing by the PU 18A and displays the charge / discharge state of the storage battery 15, a storage unit 18F that stores measurement values and control programs, and a power supply unit 18G that is a voltage source of each IC such as the CPU 18A. Have been.

In the charge / discharge control monitoring section 18C, the solar cell 1
7, a charging circuit for charging the storage battery 15, a power supply circuit for the lamp 12, a charge / discharge control means, and the like are provided, and the functions of the lamp 12, the storage battery 15, and the solar cell 17 are measured along with these circuits. Detection circuit is provided. The state of charge of the storage battery 15 as the power source of the lamp 12 by the output current of the solar cell 17 and the state of discharge of the storage battery 15 by lighting of the lamp 12 and the like are monitored.

First, the charge / discharge control / monitoring unit 18C is configured to monitor the functions of the lamp 12, the storage battery 15, and the solar battery 17, and the lamp 12 is turned on and off and the lamp 12 is disconnected. The load current is detected to detect (short circuit), the output voltage (storage battery voltage) and the charging / discharging current of the storage battery 15 are detected, and the temperature of the storage battery 15 is detected by the temperature sensor 21. , Its output current is detected.

The output which is the inspection item of each of these devices is as follows:
Based on the remote control signal Ia from the remote control transmitter / receiver 19, the charge / discharge control monitoring unit 18C selectively selects the measuring unit 18D.
Is converted to a digital signal and sent to the CPU 18A. The CPU 18A performs signal processing on the measured values. The measurement data is transmitted by infrared
It is transmitted over the 8 _2. In addition, each inspection item is periodically measured, and the measurement data is stored in the storage unit 18F. These measurement data can also be called out by the remote control transceiver 19.

The basic function of the charge / discharge control monitoring unit 18C will be described. The storage battery 15 is charged by the output current from the solar cell 17, and the storage battery voltage E is compared with the overcharge prevention operation voltage E1, The charge function return voltage E2, the overdischarge prevention operation voltage E3, and the discharge function return voltage E4 are monitored. For example, the terminal voltage of the storage battery 15 is 12V, the overcharge prevention operation voltage E1 is 13.8V,
The charge function return voltage E2 is 13.2 V, the overdischarge prevention operation voltage E3 is 10.8 V, and the discharge function return voltage E4 is 1
It is set to 2.0V.

In the charge / discharge control means of the storage battery 15 of the charge / discharge control monitoring unit 18C, when the storage battery voltage E of the storage battery 15 reaches the overcharge prevention operation voltage E1 (13.8V), charging is stopped, and the storage battery 15 When the storage battery voltage E reaches the charging function return voltage E2 (13.2 V), charging is started again. When the storage battery voltage E of the storage battery 15 decreases to the overdischarge prevention operation voltage E3 (10.8 V), the discharge of the storage battery 15 is stopped, and only the charging is performed. When the storage battery voltage E becomes the discharge function return voltage E4 (12.0
When V) is reached, the discharge starts again. Thus, the storage battery voltage E of the storage battery 15 is constantly monitored.

The light-emitting display section 18E has a light-emitting diode, and the charge / discharge state of the storage battery 15 is determined by the CPU 1.
At 8A, the state of charge and discharge of the storage battery 15 is displayed by turning on the light emitting diode. For example, a fast blinking cycle of about 0.5 seconds is used for overcharging, and a slow blinking cycle of about 4.0 seconds for overdischarging. If it is in a normal state, it is turned on immovably. This operation involves turning on and off the light emitting diode by remote control,
At the same time, the lighting can be turned on and off manually.

Next, the remote control transceiver of the present embodiment will be described with reference to FIG. Remote transceiver, CPU 19a, memory unit 19B, an external storage device 19C such as a magnetic storage medium or a memory card, transceiver 19D consisting of a receiving unit 19 ₁ transmission unit 19 ₂ which, indicator 19E, in a key input unit 19F It is configured. Key input section 19F
Are provided with instruction buttons A to L, and can transmit a remote control signal Ia by infrared rays to the light buoy remote inspection control device 18 to read out each inspection item.

The key input section 19F is provided with instruction buttons A to L. For example, instruction button A is
OFF switches, instruction buttons BK are switches for selecting items to be monitored, B is a switch for instructing the start of measurement, C, D, E, F, and G are storage battery voltage and charging current, respectively. , A switch for measuring storage battery temperature, solar cell voltage, and load current, H is a lamp blinking cycle, J is a measured average value, K is a switch for monitoring lamp test lighting,
L is a spare switch.

Next, a method of checking the lamp 12 by the remote control transceiver 19 will be described. The maintenance of the light buoy is operated by operating the instruction buttons A to L of the remote control transceiver 19. The remote control transceiver 19 transmits a remote control signal Ia by infrared rays. On the basis of the remote control signal, signal processing is performed by the remote inspection control device 18, the data signal Ib by infrared rays from the transmitter 18 ₂
And received by the receiver 19 _1, lamp 12, the storage battery 15, it is inspected features of the devices of the solar cell 17.

First, the instruction button B of the remote control transmitter / receiver 19 is pressed on the ship, and measurement of the electric system of the light buoy is started. Remote control signal Ia an infrared transmission unit 19 ₂ of the remote control transceiver 19 is transmitted to the receiving unit 18 ₁ of the remote inspection control device 18. Receiving a remote inspection control signal Ia at the receiving portion 18 ₁ of the remote inspection control devices 18, posture receiving the remote control signal Ia is established, it is possible to send and receive inspection items.

[0031] When inspecting the battery voltage, press the instruction button C, and transmits the measurement data of the battery voltage as a data signal Ib by infrared, the transmission unit 18 ₂ of the remote inspection control device 18. Receiving a data signal Ib in the receiving portion 19 ₁ of the remote control transceiver 19, the signal processing is displayed on the display device 19E the value of the battery voltage at CPU 19a. The read storage battery voltage is stored in an external storage device 19C such as a memory card. When calculating the average value of the storage battery voltage, the instruction button J is pressed and the CPU 1
9A to calculate the average value of the storage battery voltage.
Display on E. For other inspection items, each device can be inspected by the same operation, so that the individual description is omitted. Of course, the operation of the remote control transceiver 19 is
It is not limited to this embodiment.

Next, another embodiment of the light buoy according to the present invention will be described with reference to FIG. (A) is a side view of the light buoy, and (b) is a front view thereof.
The same parts as those in FIG. 1 are denoted by the same reference numerals, and the description of the same parts will be omitted. The light buoy according to this embodiment includes a suspension ring 20 for lifting the light buoy on board and performing maintenance and inspection.
Is provided as an auxiliary tool. The lower end of the rod 20a is fixed to the weight support cylinder 4a near the fixing member 4C, and the upper end of the rod 20a is fixed to the annular support member 16. This suspension ring 20
Is placed at a relatively high position on the light buoy, so that it is possible to put the crane's hanging tool on the suspension ring 20 from above the ship, raise the light buoy, and perform inspection. Further, the rod-shaped member 20 a having the suspension ring 20 is provided with the remote inspection control device 18.
It is possible to indicate the position where the transmitting and receiving unit and the light emitting display unit are installed, and the suspension ring 20 can be easily approached to the target, and the electric system of the light buoy can be easily inspected by remote control. .

FIG. 4 is a perspective view showing another embodiment of the light buoy according to the present invention. The light buoy of the embodiment shown in the figure is different from the light buoy of FIG.
Are provided at opposing positions. Remote inspection control equipment 1
As shown in FIG. 5, the transmitting and receiving units 18B and 18B 'and the light-emitting display unit 18 correspond to one remote control circuit unit as shown in FIG.
E and 18E 'are respectively provided at two places. The light-emitting display portions 18E, 18E 'and the like face the direction in which the suspension ring 20 is provided. As shown in the block diagram of FIG. 5, the light buoy remote inspection control device 18 is
8E, 18E 'and transmission / reception units 18B, 18B' are provided in parallel. Therefore, since the remote inspection operation can be performed from two directions by the remote control transmitter / receiver 19, the maintenance inspection operation is facilitated.

FIG. 6 is a partial perspective view showing another embodiment of the light buoy according to the present invention. FIG. 2A shows another example of the floating body 10 of the light buoy according to the embodiment, and FIG. 2B is a perspective view showing segments constituting the floating body 10. The floating body 10 having an annular structure includes a plurality of divided segments 10a to 1
0d, each segment is annularly combined around the stopper 10e, and is fixed with bolts and nuts. A cylindrical weight supporting cylinder 4a is inserted into the stopper 10e. The segments 10a to 10d are made of the material and structure described above. Of course, the number of segments constituting the floating body is not limited to the above embodiment.

[0035]

As described above, according to the first aspect of the present invention, a remote control signal using infrared light of a light buoy is transmitted to a remote inspection control device to charge a lamp, a storage battery as a voltage source thereof, and a storage battery. This is a light buoy which has the effect of receiving those data from a position away from the function of the solar cell to perform the inspection and checking the electric system of the light buoy.

Further, according to the invention of claim 2, there is provided a light buoy having an effect that even if a part of the floating body is damaged, it can be repaired only by replacing the part.

According to the third aspect of the present invention, the remote control signal of the light buoy is received by the remote inspection control device, and the lamp, the storage battery as a voltage source thereof, and the solar battery for charging the storage battery are received. Is a remote inspection control device for a light buoy having an effect of transmitting each of the functions.

According to the fourth aspect of the present invention, a remote control signal by infrared rays can be transmitted to a remote inspection control device mounted on a light buoy, and data can be read from the remote inspection control device. Has an effect.

According to the fifth aspect of the present invention, the buoy has an effect that each data can be processed, displayed, and stored by the external storage device mounted on the remote controller for the light buoy. Light buoy remote inspection control system, which consists of a remote control transmitter / receiver for buoys and a remote inspection control device for buoys that can transmit data in response to a request from the remote control transmitter, and can inspect the electric system of the light buoy from a remote location It is.

According to the sixth aspect of the present invention, since the suspension ring for lifting the light buoy is provided above the light buoy, if a defective part is confirmed by the remote inspection control, an inspector is required. Since the light buoy can be repaired without being transferred to the light buoy and relatively unaffected by marine conditions, the light buoy has an excellent safety effect.

[Brief description of the drawings]

FIG. 1A is a side view showing an embodiment of a light buoy according to the present invention, FIG. 1B is a plan view thereof, and FIG. 1C is a view showing an embodiment of the remote control transceiver. .

FIG. 2 is a block diagram showing a remote inspection control device for a light buoy, a remote control transceiver for the same, and a remote inspection control system for the same according to the present invention.

FIG. 3A is a side view showing another embodiment of the light buoy according to the present invention, and FIG. 3B is a plan view thereof.

FIG. 4 is a perspective view showing another embodiment of the light buoy according to the present invention.

FIG. 5 is a block diagram showing another embodiment of a remote inspection control device for a light buoy, a remote control transceiver for the same, and a remote inspection control system for the same according to the present invention.

FIG. 6A is a partial perspective view showing another embodiment of the light buoy according to the present invention, and FIG. 6B is a partial view thereof.

FIG. 7 is a side view showing an example of a conventional light buoy.

[Explanation of symbols]

 Reference Signs List 4 weight 4a weight supporting cylinder 4b, 4c fixing member 4d connecting part 4e hanging ring 10 floating body 11 head mark 12 lamp 13 day mark board 14 display board 15 storage battery 16 annular support member 17 solar cell 18 remote inspection control for light buoy Equipment 19 Remote control transceiver 20 Hanging ring

Claims (6)

[Claims] 1. A light buoy having a weight at a lower part of a floating body and a lamp at an upper part thereof, wherein the light buoy is provided with a storage battery which is a power source of the lamp and a solar cell for charging the storage battery. Charge / discharge control means for controlling the state of charge of the storage battery by the solar cell and the state of discharge of the storage battery; measuring means for measuring the functions of the lamp, the storage battery, and the solar cell; and infrared rays from a remote control transceiver. At least one receiving unit for receiving a remote control signal according to the following, and an arithmetic processing unit that receives the remote control signal at the receiving unit and performs signal processing on an output signal from the measuring unit according to a command of the remote control signal; An indicator for displaying the charge / discharge state of the storage battery by processing by the arithmetic processing means; and superimposing data of the lamp, the storage battery, and the solar cell on infrared rays based on the remote control signal. Light buoy characterized in that it comprises a remote inspection control device and at least one transmission unit for transmitting Te. 2. The light buoy according to claim 1, wherein the floating body is an annular body formed by connecting at least two segments each including a porous member as a filler. 3. A charge / discharge control means for controlling a state of charge by a solar cell of a storage battery as a power supply of a lamp provided on a light buoy, and a state of discharge of the storage battery by energizing the lamp or the like, Measuring means for measuring a lighting state of a lamp, an output voltage of the storage battery, an output current of the solar cell, and the like; at least one receiving unit for receiving a remote control signal by infrared rays from a remote control transceiver; and the remote control An arithmetic processing unit for performing signal processing on an output signal from the measuring unit in accordance with a signal instruction; at least one transmission unit for transmitting data of the lamp, the storage battery, and the solar cell; and a display for displaying a state of charge of the storage battery And a remote inspection control device for a light buoy. 4. A transmission unit for transmitting a remote control signal by infrared rays to the remote inspection control device for a light buoy according to claim 1, 2, or 3, and receiving data from the remote inspection control device. At least one receiving unit, arithmetic processing means for performing signal processing on the data, a display for displaying an arithmetic result by the arithmetic processing means, an external storage means for storing the arithmetic result, and remotely controlling the remote inspection control device. And a key input unit for generating a command for controlling and a command for causing the arithmetic processing unit to perform signal processing on the data. A light buoy remote control transceiver. 5. The remote control device for light buoy according to claim 1, 2, or 3, and the remote control transceiver for light buoy according to claim 4, wherein the function of the light buoy is controlled by infrared rays. A remote inspection control system for a light buoy, wherein the remote inspection is performed by data transmission. 6. The light buoy according to claim 1, further comprising at least one rod-shaped member provided with a suspension ring for raising the light buoy for maintenance and inspection. Light buoy.