KR20050006481A - Marking buoy device using wave-force generation - Google Patents

Abstract

PURPOSE: A mark floating apparatus is provided to improve the efficiency, to excellently operate functions of main units in a rough sea-weather condition and to improve the durability by converting wave force to electric energy. CONSTITUTION: A supporting member is combined with an upper and a lower supports(12,14) and a pair of guide rods(18) vertically. A mark light(10) is combined with the upper part of the upper support. A resistance plate(20) moves the guide rods upward and downward by forming in a downward curvature. An operating device drives a generator(40) by the vertical movement of a shaft(34) and a floating(30) to be combined with the resistance plate and charges a battery(50) through a charging controller(52). A buoyancy member(5) is a cylindrical shape to generate the buoyancy by combining with the middle of the supporting member. The buoyancy member stores the operating device in an additional space hermetically. A flickering controller(54) operates the mark light in a preset flickering cycle by installing in the upper support. Thereby, a mark floating apparatus emits light by converting wave energy to electric energy.

Description

Marking buoy device using wave-force generation

The present invention relates to a marker buoy mechanism, and more particularly, has high efficiency in converting wave energy into electrical energy to emit light, and makes the function of the main operation part excellent in tough post-sealing conditions and at the same time increases durability. The present invention relates to an improved marker buoy mechanism using wave power generation.

In general, the marker buoy is installed at sea to emit light at night, and it is mainly used for guiding the safe passage of the ship to prevent various human and material damages. It is also used to inform fishermen who depend on aquaculture for the location of fishing nets, and the demand is increasing year by year.

However, if such a marker member relies only on the battery for the operation power for emitting light such as a marker, it is not only inconvenient to replace the battery frequently, but also requires thorough battery management, so there is little practicality or management inconvenience. Means are required, and at this time, a method of charging the battery from time to time by providing a wave power generator using the kinetic energy of waves has been proposed.

However, since the magnitude and frequency of offshore waves are not kept constant and the magnitude of change is great in each region and season, the efficiency of power utilization through wave power generators is very important, especially in bad weather with strong winds. The situation is accompanied by technical difficulties that must be closely operated so as to be properly operated and protected from the impact of external collision or seawater penetration, or the measures against it are very insufficient.

Accordingly, the present invention has been devised in view of the above points, the efficiency is good in converting the wave energy into electrical energy to emit light, and the function of the main operation unit is excellent at the same time, even under the harsh post-sea conditions, and at the same time durable. It is an object of the present invention to provide a marker buoy mechanism using wave power, which is greatly improved.

1 is an exploded perspective view of a device according to an embodiment of the present invention;

2A and 2B are configuration diagrams showing the assembled state of the apparatus of FIG. 1 in front and plane;

Figure 2c is an exploded perspective view showing an enlarged portion of the gearbox of the mechanism of Figure 1,

3 is an enlarged cross-sectional view showing another embodiment of the rack of the instrument of FIG.

Figure 4 is an enlarged perspective view of the cut off one surface of the upper support according to the invention,

5 is an enlarged perspective view of a spring and a spring adjustment bolt portion according to the present invention;

6 is an enlarged perspective view of a casing portion according to the present invention;

7 is a view of various embodiments of a portion of a resistance plate according to the present invention;

8 is a configuration diagram of an electrical circuit portion according to the present invention;

9 is a view of several embodiments of the anchor string portion according to the present invention,

10 is a schematic diagram showing the mechanism operating state of FIG.

11 is an exploded perspective view of a device according to another embodiment of the present invention;

12A and 12B are configuration diagrams showing the assembled state of the mechanism of FIG. 11 from the front and the plane;

12c is an exploded perspective view showing an enlarged portion of a gearbox of the mechanism of FIG. 11;

Explanation of symbols on the main parts of the drawings

10: mark 12, 14: support

16: fixture 18: guide rod

20: resistance plate 26: holder

30: Float 32: Gearbox

34: shaft 40: generator

50: battery 52: charge controller

54: flashing controller

In order to achieve the above object, the present invention provides a mechanism for generating a wave power and storing the battery 50 at the same time, and emitting the indicator lamp 10: the upper and lower supports 12 and 14 and a pair of guide rods ( 18 is vertically coupled, the support member to which the marker lamp 10 is coupled to the upper end of the upper support 12; A resistance plate 20 which is formed to have a downward curved surface, and enables the up and down movement of the guide rod 18; The generator 40 is driven by the up and down movement of the shaft 34 and the floating body 30 coupled to the resistance plate 20, and charges electricity to the battery 50 through the charge controller 52. Operating means; A buoyancy member (5) coupled to the middle of the support member to generate a buoyancy force, the airtight member (5) for hermetically receiving the operating means in a separate space; And a flashing controller 54 installed on the upper support 12 while allowing the indicator lamp 10 to operate at a set flashing cycle.

The upper support 12 of the support member according to the present invention forms a guide piece 12a that can be opened and closed on one side, and the partition plate 13 is installed inside the guide piece 12a, but in the space therebetween. Accepts wires 15.

As an example of the present invention, the buoyancy member 5 is provided with a gear box 32 to be exposed to the upper surface of the floating body 30, the airtight using the casing 36, 46 in the gear box 32 Keep it.

As another example of the present invention, the buoyancy member 5 is provided with a gear box 62 to be recessed on the upper surface of the floating body 30, using the casing 36, 46 in the gear box 62 To keep it confidential.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing a mechanism according to an embodiment of the present invention, Figures 2a and 2b is a block diagram showing the assembly state of the instrument of Figure 1 in front and plan view, Figure 2c is a gearbox portion of the mechanism of Figure 1 An exploded perspective view showing an enlarged view.

The present invention relates to a mechanism that generates power by wave power and stores the battery 50 at the same time. The indicator lamp 10 is a lamp operated by a direct current power source and may have a reflector. The battery 50 may have a capacity between DC 1.5V and DC 24V. Among them, a DC 12V capacity is most preferable, and a DC 24V capacity used for starting a marine engine can also be used. .

According to the present invention, a support member in which the upper and lower supports 12 and 14 and the pair of guide rods 18 are vertically coupled is used. The upper support 12 is a marker lamp 10 is coupled to the upper end, the lower end is formed in the form of a wide flange 70 diameter. Detailed configuration of the upper support 12, see Figure 4 to be described later. The lower support 14 is formed with a spiral portion 14a at the upper end and a flange 71 in the middle, and the fixture 16 of the ∞ form is integrally formed at the bottom. The pair of guide rods 18 is fixed to the lower end of the lower support 14 using the fixture 16 and the fixture 26 up and down. 'Leads to form. The guide rods 18 may be formed of three guide rods 18, not necessarily a pair. In addition, the pair of guide rods 18 are installed to be supported in parallel through the fixing rod 26 of the ∞ form consisting of the fastener 100 and the shock absorbing groove 101 at the bottom. In addition, the fixing table 26 is provided with a binding hole 100 for binding the anchor string 110 in the downward direction, and at the same time, a cushioning piece 102 in the lower portion of the resistance plate 20 to mitigate an impact with the resistance plate 20. The shock absorbing groove 101 is formed to receive the shock absorbing groove 101 and the buffer piece 102 is to prepare for the possibility that the resistance plate 20 and the fixing table 26 suddenly hit. . In addition, the upper and lower supports 12, 14 and the guide rods 18 arranged in a straight line are all hollow pipes, and in particular, the guide rods 18 are made of steel having excellent mechanical strength and corrosion resistance. Use iii).

The resistance plate 20 of the present invention is configured to allow the up and down movement of the guide rod 18. That is, the resistance plate 20 serves as a crutch when the guide rods 18 installed on both sides of the resistance plate 20 move up and down. In other words, when the floating body 30 rises up by the waves, the guide rod 18 also rises together. At this time, the resistance plate 20 is the resistance plate 20 due to the balance between the pressure of the water and the buoyancy that is pushed down. The shaft 34, which is firmly bound to the resistance plate 20, is fixed in an almost floating position while being held almost without moving in the original position. On the other hand, the guide rod 18 connected to the floating body 30 is generated by various configurations in the gear boxes 32 and 62 while rising upward with the floating body 30. Therefore, as the propulsion role of the resistance plate 20 is emphasized, and as the ascending width of the guide rod 18 increases, the amount of power generation increases, so considering the efficiency of power generation, the resistance plate 20 is heavy, and the floating body 30 is The lighter the better. Such a resistance plate 20 may be formed in a downward curved surface or a planar shape, and may also simultaneously configure a plurality of resistance plates 20 in addition to a single resistance plate 20, which will be described later in FIG. 7. It demonstrates in detail.

As shown in FIG. 2A, the guide bushes 112 and 113 are attached to upper and lower portions of the lower support 14, and a guide bush fixing bracket 114 is installed at the bottom of the lower guide bush 113. In order to increase the binding force between the resistance plate 20 and the shaft 34, the fastening bolt 90 is pushed into the lower end of the shaft 34 from the bottom of the resistance plate 20 to be tightened, and then again the resistance plate. The stainless steel washer 91 and the bracket 92 are padded on the upper and lower portions of the 20, and fastened securely with the coupling bolt 93 and the fastening nut 94, and are extended in the direction of the ear shaft 34. After fastening the side tightening bolts 95 to both sides of the bracket 92, a buffer piece 102 such as rubber material is installed on the upper side tightening bolts 95. In addition, there are various methods of fastening the resistance plate 20 and the shaft 34 to each other in addition to the above-described examples, but the resulting actions and effects will all be the same.

Further, according to the present invention, the generator 40 is driven by the up and down movement of the shaft 34 and the floating body 30 coupled to the resistance plate 20, and the battery 50 through the charge controller 52. An actuating means for charging is used. The shaft 34 having the racks 34a and 34a 'on one side is received in the interior of the lower support 14 and connected to the center of the float 30 at the bottom and to the spring 39 at the top. In addition, the pinion 44 is engaged with the racks 34a and 34a 'of the shaft 34 to drive the generator 40 in a rack / pinion motion similarly to the conventional case, but the operating means of the present invention is in addition to the driving means. A speed increase gear 42 and a driven gear 43 may be further provided between the pinion 44 and the generator 40.

In addition, the operating means of the present invention includes a charge controller 52 between the generator 40 and the battery 50. It includes a regulator function that adjusts the magnitude of the current to the magnitude of the voltage to be charged, and also performs a function of blocking overcharge when the battery 50 approaches full charge at the set voltage. However, since the generator 40 continuously rotates in the forward and reverse directions, the charging controller 52 has a function of rectifying the output generated during the forward and reverse rotation of the generator 40.

In addition, according to the present invention is a tubular structure coupled to the middle of the support member to generate a buoyancy, buoyancy member (5) is used to receive the operating means to be hermetically sealed in a separate space. According to one embodiment of the present invention, the buoyancy member 5 is provided with a gear box 32 to be exposed to the upper surface of the floating body 30, the airtight using the casing 36, 46 in the gear box 32 Keep it. As shown in FIG. 2A, the lower flange 70 of the upper support 12 is coupled to the cover 38 of the gearbox 32, and the intermediate flange 71 of the lower support 14 is connected to the float 30. It is coupled to the lower end, the upper end of the lower support 14 is coupled to the lower end of the gearbox (32). Inside the gearbox 32, the first casing 36 is installed coaxially with the upper and lower supports 12 and 14. That is, the upper and lower supports 12 and 14 are not directly connected, but are connected to each other via the first casing 36. The casings 36 and 46 are an important part for engaging the racks 34a and 34a 'and the pinion 44 of the shaft 34 and determining the airtightness in the gearbox 32, the details of which will be described later. See FIG. 6.

In FIG. 2B, it can be seen that the battery 50 and the generator 40 are arranged to be in a symmetrical position about the shaft 34, and the battery 50 is firmly fixed by the battery fixture 59. In addition, the battery 50 may be installed in another place instead of the gearbox 32. As shown in FIG. 2C, the racks 34a, 34a ′ and pinion 44 are housed in the casings 36 and 46 and the gearbox 42 and the driven gear 43 are mounted on the gearbox frame 45. Although it is internally installed, they are rotated while being engaged with each other, and at the same time, the generator 40 is installed at one side of the driven gear 43. The generator 40 is preferably used having a function equivalent to or higher than a stepping motor age. The rotation ratios of the racks 34a, 34a ', the pinion 44, and the increase gear 42 are 1: 1, and the rotation ratios of the increase gear 42 and the driven gear 43 are set to about 1: 3. Although this is preferable, the rotational ratio can be adjusted as much as possible, and the larger the rotational ratio of the speed increasing gear 42 and the driven gear 43, the greater the amount of power generation. In addition, in the case of the driven gear 43, it is not an essential gear to be configured. For example, when the wave force is high, it may not be installed to prevent overcharge, but in the opposite case, the second and third driven gears are added. You can also install

In the gearbox 32, reference numerals 81 and 82 denote speed increase gear shafts and ball bearings, 83 are fixed brackets for fixing the speed increase gear shafts and ball bearings, 84 are driven gear shafts, and 85 and 86 are for motor fixing. Support rods and ball bearings, 87 and 88 are another fixing bracket and coupling. And reference numerals 31 and 61 on the floating body 30 is a handle that is attached to be easy to hold by hand when moving or lifting the mechanism of the present invention.

On the other hand, according to the present invention includes a flashing controller 54 installed on the upper support 12 so that the indicator lamp 10 is operated in a set flashing cycle, the upper portion of the flashing controller 54, the light bulb 54a is formed And the bulb 54a is inserted inside the marker lamp 10. The flashing controller 54 may be constituted by an IC circuit or may simply use a timer relay, which varies the task of on / off operation for the indicator lamp 10 through an adjustment knob (not shown). In addition, the illumination sensor 54b may be added to one side of the flashing controller 54 so that the indicator lamp 10 operates only at night.

3 to 7 are cross-sectional views, perspective views, and plan views partially showing the main components of FIG. 1.

3 is an enlarged cross-sectional view of various embodiments of racks of the instrument of FIG.

That is, as shown in the case of the shaft 34 shown in Fig. 2a, the rack 34a is immediately formed on one end surface of the shaft 34 made of stainless material or equivalent material (material that can prevent corrosion). However, as shown in FIG. 3A, a small diameter stainless shaft 34b is installed at the upper end of the shaft 34 to weld and fix the primary contact region between the shafts 34 and 34b and at the same time. After firmly binding with the finishing pin 34c, the rack 34a 'made of Teflon resin or the like may be inserted on the outer side of the shaft 34b. At this time, the rack 34a 'can be manufactured by the shaft 34b and the insert injection method. Also, as shown in FIG. 3B, after inserting the lower binding piece 140 inside the upper end of the shaft 34, the stainless steel shaft 34b having a small diameter is installed in the lower binding piece 140, and the primary parts thereof are installed. At the same time as welding and fixing the contact area, the shaft 34 and the lower binding piece 140 are again firmly fixed with the finishing pin 34c, and then the hard resin material is formed on the outer circumferential surface and the upper inner side of the shaft 34b having a small diameter. The rack 34a 'and the upper binding piece 141 having a thread may be installed in this order. And as shown in Figure 3c the diameter of the lower end portion is thick, the upper end portion of the thin shaft 34, the outer surface of the top of the hard resin material (34a ') may be covered by the insert injection method. As described above, the rack may be implemented in various forms, but among these, the embodiments of FIGS. 3B and 3C are preferable.

When the rack 34a 'formed of a hard resin material such as Teflon is engaged with the pinion 44, which will be described later, the pinion 44 is also made of Teflon resin, so that even if used for a long time, the wear is not severe to each other or the rack 34a' is used. ) And pinion 44 have a similar degree of wear, and their lifespan is long. However, when the rack 34a made of stainless steel and the pinion 44 made of Teflon resin are engaged, the degree of wear of the pinion 44 is increased. There is concern. Therefore, in the case of rack and pinion, it is preferable to use the same material, but in order to prevent corrosion, stainless shaft 34 must be used. Therefore, if the material of the rack and pinion is used differently, their coupling structure is slightly as described above. Can vary However, whatever the coupling structure of the shafts 34 and 34b, the lower spring adjustment bolt 56 is inserted into the top end of the shafts 34 and 34b.

In Figure 4 is an enlarged perspective view showing a cut off one surface of the upper support according to the present invention.

That is, the upper support 12 according to the present invention forms a guide groove 12a that can be opened and closed on one side, and the partition plate 13 is installed inside the guide piece 12a to connect the electric wire 15 in the space therebetween. And a spring 39 in the space on the opposite side thereof. And inside the upper support 12, the spring 39 is operated up and down, thereby protecting the wire 15 is connected from the battery 50 to the indicator lamp 10 because the wire 15 is affected. In order to do so, it is preferable to form a separate hermetic space part.

In FIG. 5, the top and bottom spring adjustment bolts 55 and 56 are shown.

The upper and lower spring adjustment bolts 55 and 56 have a plurality of closing holes 57 formed therein, and the upper and lower ends of the springs 39 are finished in these closing holes 57. Therefore, when the float 30 descends due to the wave, the spring 39 increases for a while due to the weight of the float 30, and when the float 30 rises again due to the overflowing wave, the spring 39 ) Again to lift up the heavy lifting weights 30 to help rise of the lifting weights (30). As a result, the lifting and lowering of the floating body 30 is very easy, and the efficiency of power generation can be greatly increased. And the upper and lower spring adjustment bolts 55 and 56 perform the function of adjusting the tension of the spring (39).

6 shows the casings 36 and 46 in the gearbox 32.

In FIG. 6, the first casing 36 has a rectangular opening 36a formed on one surface thereof, through which the racks 34a and 34a 'of the shaft 34 are exposed. Between the box-shaped second casing 46 having the opening 46a on one surface and the opening 36a of the first casing 36, a waterproof packing 46b is improved. The pinion 44 is accommodated in the second casing 46. The shaft of the pinion 44 is hermetically maintained through a V ring 46d surrounding the opening 46c of the second casing 46, and the speed increasing gear 42, the driven gear 43, and the generator 40 are maintained. ) In turn. Accordingly, even if the seawater penetrates the lower support 14 and reaches the racks 34a, 34a 'and the pinion 44, the gearbox 32 is sealed by the casings 36 and 46. The electrical main components such as generator 40 and battery 50 are safe.

In Figure 7 several exemplary views of the resistive plate portion according to the invention are shown.

In FIGS. 7A and 7B, the resistance plate 20 has a disk shape having a curvature R on the bottom thereof, and a boss portion 20b is formed at the center thereof, and through holes 20a are formed at both sides thereof. If the curvature R is flat or the curvature R is placed upward, the residue is likely to accumulate. On the other hand, if the disk is configured as shown, the resistance of the wave is slightly weakened, but the durability is good. The lower end of the shaft 34 is coupled to the boss portion 20b, and the guide rod 18 is inserted into the through hole 20a to slide up and down. A lattice bead 20c is formed on the bottom of the resistive plate 20.

In addition, in FIG. 7C, another resistance plate 21 formed in a donut shape outside the center resistance plate 20 is formed to be connected to the connecting shaft 22. In FIG. 20) It is shown that the plurality of resistance plates 23 are addressed to each other through a plurality of connecting shafts 22 on the outside. When a plurality of resistance plates are formed in addition to the single resistance plate 20 as described above, the resistance of the resistance plate 20 becomes stronger, and thus the lifting and lowering movement of the floating body 30 becomes very active, thereby improving power generation. The large or large resistance plates 20, 21, 23 do not necessarily improve the power of generation greatly.

On the other hand, it is as described above to provide a cushioning piece 102, such as a rubber material so as to buffer when the resistance plate 20 collides with the fixture 16 and the holder 26 while raising and lowering.

8 shows a process of representing an electrical circuit according to the invention.

That is, the generator 40 is driven by the up and down movement of the shaft 34 and the floating body 30 installed in the lower support 14, but once the power is generated, the battery is secondarily passed through the charge controller 52. Charged by 50, the wire 15 connected to the battery 50 has a structure leading to the indicator lamp 10 via the flashing controller 54. However, in the case of the battery 50, even if the self-generation is not made through the generator 40, the first 25 to 30 days can be generated by themselves, but after that if there is no self-generation through the generator 40 (marker etc.) 10) cannot be turned on. Therefore, self-power generation through raising and lowering of the floating body 30 is essential, but as long as there is a wave, the lifting and lowering movement of the floating body 30 and the self-powering through the generator 40 are not only sufficient, but also the degree of charge is increased. Even if the battery 50 is excessively followed, a charge controller 52 is formed to prevent overcharging. However, the charge controller 52 may be omitted in an area having a weak wave.

9 is a schematic showing various embodiments of anchor strings.

That is, in FIG. 9A, the anchor string 110 is sealed at the binding hole 100 formed at the center of the fixing rod 26 having the shape of ∞, and the anchor 111 which is in contact with the bottom surface of the sea at the tip of the anchor string 110. Is addressed. In the case of FIG. 9B, a weight body 112 formed of cement or the like is connected to the tip of the anchor line 110, which is useful when the bottom of the sea is made of sand and thus the role of the anchor 111 is insignificant. In addition, in the case of FIG. 9C, the front end portion of the anchor line 110 is hung on the fishing line 105 under the sea to show an example of preventing the floating object 30 from floating freely. Therefore, the float 30 will rise and fall as long as the float 30 is not floated by the anchor line 110 regardless of which way the descending 30 is raised or lowered. Then, the power generation is possible. The main reason why the guide rods 18 are formed on both sides of the resistance plate 20 is that the guide rods 18 are hardly distorted when the floating body 30 moves up and down in a zigzag form. To descend. In addition, the anchor wire 110 may be bound to a lower portion of the resistance plate 20 or a certain point of the floating body 30 without being sealed to the binding hole 100, but in the case of the resistance plate 20, a large wave There is a fear that the spring (39) is broken when it rises, on the other hand, when the anchor 30 is sealed there is a fear that the anchor string 110 is twisted due to the float 30 rotates back and forth by the wave force. Therefore, in consideration of the above-described aspects, it can be said that the anchor line 110 is most preferably sealed to the fastener 100 of the fixing table 26.

10 is an operational state diagram of the instrument shown in FIG. 1.

Since the lower part of the mechanism including the resistance plate 20 is a heavy body, it is generally maintained in a vertical state as shown. In accordance with the up and down movement of the wave, the resistance plate 20 maintains substantially the same height, but the relative movement occurs while the floating body 30 is linked to the digging, and then the up and down movement of the floating body 30 is induced. The generator 40 is operated while the gear is operated in the order of the pinion 44, the speed increase gear 42, and the driven gear 43. The electricity generated by the generator 40 is stored in the battery 50 and at the same time, the indicator lamp 10 is driven to emit light at a predetermined period by the blink controller 54.

Figure 11 is an exploded perspective view showing a mechanism according to another embodiment of the present invention, Figures 12a and 12b is a block diagram showing the assembled state of the instrument of Figure 11 in front and plan view, 12c is a gearbox portion of the mechanism of Figure 11 Figure is an enlarged view.

As another example of the present invention, the buoyancy member 5 is provided with a gear box 62 to be recessed on the upper surface of the floating body 60, using the casing 36, 46 in the gear box 62 To keep it confidential. To this end, the shape of the floating body 60 and the gearbox 62 is slightly different. Recessing the gearbox 62 to the float 60, as shown in Figure 12a has the advantage that the overall center of gravity is lowered in terms of maintaining the mechanism vertical, the main electrical configuration of the generator 40, battery 50, etc. There is a drawback to the need for attention to airtightness close to the sea level.

However, in the case of FIG. 11, the overall configuration is the same as that of FIG. 1, but when the installation direction of the generator 40 is changed, a gearbox frame 65 having a new shape is required instead of the gearbox frame 45 of FIG. 1. Do. In addition, as shown in 12b and 12c, the gearbox frame 65 tends to be somewhat larger in order to balance the generator 40 and the battery 50 in a symmetrical position. However, the configuration and operation of the casings 36 and 46 are the same as in the example of FIG. 1 described above.

In addition to the embodiment of Figure 11, the installation direction of the handle 61 is installed on the upper surface of the floating body 60 is changed, the shape of the cover 68 mounted on the top of the gear box 62 is slightly different , There is a difference that the lower support 14 is changed to the structure of fastening with a plurality of bolts at the top, there is no other structural difference, there is no difference in action and effect.

According to the above configuration and operation, the present invention has good efficiency in converting wave energy into electrical energy to emit light, and in the difficult post-season conditions, the function of the main operation part is excellently operated and at the same time, the durability is greatly improved. There is.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments and that various modifications and variations can be made without departing from the spirit and scope of the present invention, and therefore such modifications or Modifications should be within the scope of the claims of the present invention.

Claims (11)

In a mechanism that generates power by wave power and stores the battery 50 at the same time, the indicator lamp 10 emits light. A support member to which upper and lower supports 12 and 14 and a pair of guide rods 18 are vertically coupled, and the marker lamp 10 is coupled to an upper end of the upper support 12; Resistive plate is formed in a downward curved surface, the resistance plate 20 to enable the up and down movement of the guide rod (18); Operating means for driving the generator 40 by moving the shaft 34 and the floating body 30 coupled to the resistance plate 20 and charging the battery 50 through the charge controller 52; A buoyancy member (5) coupled to the middle of the support member to generate a buoyancy force, the airtight member (5) for hermetically receiving the operating means in a separate space; And Marking buoy mechanism using wave power generation, characterized in that it comprises a flashing controller (54) installed on the upper support (12), while the marker light (10) is operated in a set flashing cycle. The method of claim 1, The buoyancy member 5 is provided with a gear box 32 to be exposed to the upper surface of the floating body 30, characterized in that to maintain the airtight by using the casing (36, 46) in the gear box (32). Marking buoy mechanism using wave power generation. The method of claim 1, The buoyancy member 5 is provided with a gear box 62 to be recessed on the upper surface of the floating body 60, characterized in that to maintain the airtight by using the casing (36, 46) in the gear box 62. Marking buoy mechanism using wave power generation. The method of claim 1, The upper support 12 forms a guide piece 12a that can be opened and closed on one side, and installs the partition plate 13 inside the guide piece 12a, but accommodates the wire 15 in the space therebetween. A marker buoy mechanism using wave power. The method of claim 1, The upper spring adjustment bolt 55 and the spring 39 and the lower spring adjustment bolt 56 in order to be installed in the upper support member 12, but formed in the upper and lower spring adjustment bolts 55, 56 Marking buoy mechanism using a wave power generation, characterized in that the upper and lower ends of the spring (39) is finished in the closing hole (57). The method of claim 1, The rack 34a may be immediately formed on one end surface of the shaft 34 or the resin rack 34a 'may be overlaid on the outer peripheral surface of the upper end of the shaft 34, and the diameter of the shaft 34 may be small. And a rack (34a ') made of resin material on the outer circumferential surface thereof after inserting the shaft (34b). The method of claim 2 or 3, The casings 36 and 46 interpose a rectangular packing 46b between the box-shaped second casing 46 having an opening 46a on one surface thereof and the opening 36a of the first casing 36. The shaft of the pinion 44 accommodated in the second casing 46 maintains hermeticity through a V-ring 46d surrounding the opening 46c of the second casing 46. Marker Buoy Organization. The method of claim 2 or 3, The gearbox frame (45) (65) of the gearbox (45) and (65) inside the gearbox (45) and the gear (44) meshing with the shaft of the pinion (44) in turn and at the same time the driven gear ( 43) Marker buoy using wave power generation, characterized in that the generator 40 is configured to be in contact with each other. The method of claim 1, Another resistor plate 21, formed in a donut shape on the outside of the resistor plate 20, is connected to the connecting shaft 22 or the plurality of resistor plates 23 are spoken through the plurality of connecting shafts 22. Marking buoy mechanism using wave power, characterized in that. The method of claim 1, The charging of the battery 50 and the light emission of the indicator lamp 10 may be charged through the generator 40 and the charge controller 52 or may be emitted through the blink controller 54, but the charge controller 52 or the blink controller ( 54) Mark buoy mechanism using wave power, characterized in that the configuration may be omitted. The method of claim 1, The anchor line 110 is a marker buoy mechanism using a wave power generation, characterized in that can be sealed in the resistance plate 20 or the floating body 30 in addition to the binding hole 100 of the fixing table (26).