KR20120024269A - Offshore combind generator - Google Patents

Abstract

PURPOSE: A combined offshore generating device is provided to prevent damage to an impeller against strong wind by controlling the direction of wind blowing toward the impeller. CONSTITUTION: A combined offshore generating device comprises a floating member(10), an anchor(20), an upper frame(30), a lower frame, a wind power generating unit(50), a wind direction control unit(80), and an ocean current power generating unit. The wind power generating unit is installed on a first rotation rail(33) and a second rotation rail and comprises a plurality of first impellers to rotate with wind and generate electricity. The wind direction control unit controls the direction of wind blowing toward the first impellers in order to prevent damage to the first impellers. The ocean current power generating unit is installed on a third rotation rail and comprises a plurality of second impellers to rotate with ocean current and generate electricity.

Description

Marine Combined Cycle Power Plants {OFFSHORE COMBIND GENERATOR}

The present invention relates to a marine combined cycle power plant, and more particularly, by installing a pair of impellers in the water and in the water, respectively, to simultaneously perform wind power generation using the wind power on the sea and current generation using the ocean current. It can be, and relates to a marine combined cycle apparatus that can adjust the direction of the wind toward the impeller so that the impeller is not damaged when the storm and strong winds are blown by the typhoon.

In general, electric power generation methods include fossil fuel-based thermal power generation, nuclear power generation using nuclear fission, hydropower generation using potential energy of water, solar power generation using solar energy, and tidal power generation using tidal differences. And wind power generation using kinetic energy of wind.

The thermal power generation and nuclear power generation is electricity generated by rotating a turbine in a power generator with steam generated by heat, and hydroelectric power generation is electricity generated by rotating a turbine by a drop of stored water stored in a dam. .

However, thermal power generation requires a huge construction cost along with the problem of pollution caused by the use of energy generated by the combustion of fossil fuel, and has a disadvantage of depletion of fossil fuel as a limited fuel.

Nuclear power generation uses enormous amounts of heat generated from nuclear fission of radioactive materials such as uranium as an energy source. Compared to the thermal power generation, the power generation capacity requires a huge cost to invest in facilities to block leakage of radiation. Not only is it difficult to dispose of waste, but even a minor accident has various problems such as a risk that can seriously destroy the environment.

Hydroelectric power generation does not cause pollution by converting potential energy of water stored by dams into rotational energy obtained by freezing. However, the area where power plants are constructed is limited and land of large area must be submerged. In addition, in severe cases, there are problems such as a secondary environmental problem that may change the climate of the region.

Solar thermal power generation had a problem that power generation is impossible when the solar radiation energy is blocked according to the weather conditions.

Tidal power generation is not only difficult to apply universally due to the extremely limited location conditions, but also has a problem of devastating tidal flats and enormous impact on the environment of the vast region as well as enormous construction cost burden.

Recently, various alternative energy developments have been made to solve the above problems.

Recently, the interest and development of the offshore power generation system using both wind energy and ocean current energy with low installation cost and high efficiency as energy to replace this situation has been concentrated.

Such a marine power generation device is presented in the "offshore combined cycle power generation device" of Korea Patent Publication 2004-0107165 (hereinafter referred to as the prior art), the marine combined cycle power generation device according to the prior art, the vertical support column is fixed to the seabed ground, vertical support The underwater part of the column was installed with an ocean current generator provided with an underwater propeller blade, and the upper part exposed to the water surface of the vertical support pillar was installed with a wind power generator equipped with a water propeller blade.

However, the marine combined cycle apparatus of the prior art does not have a device for protecting the water propeller blades of the wind power generation unit when a typhoon blows, so there is a problem that the water propeller blades are damaged by storms and strong winds.

In addition, the marine combined cycle apparatus of the prior art has a problem that the wind power generation is submerged in the sea to the wind power generator when the sea level rises.

The present invention has been made to solve the above problems, it is possible to perform the wind power generation using the wind power on the sea and the current generation using the ocean current at the same time, when the impeller is blown by the storm and strong winds It is an object of the present invention to provide a marine combined cycle power generation apparatus that can adjust the direction of the wind toward the impeller so as not to be damaged.

In addition, there is a purpose to provide a marine combined cycle power plant that is floating on the sea surface using a floating body, which can be installed in a wide range of the sea can be installed mobile.

The present invention for achieving the above object, the floating body having a buoyancy to float on the sea surface; An anchor connected to the bottom of the float to be supported by the sea bottom so that the float is moored to the sea surface; An upper frame installed at an upper portion of the floating body so as to be positioned in the water phase, and having a first rotating rail and a second rotating rail spaced apart from each other in a circular frame; A lower frame installed under the floating body so as to be underwater, and having a third rotary rail forming a circular frame; A wind power generation unit rotatably provided on the first rotating rail and the second rotating rail and having a plurality of first impellers and rotating in a direction in which a wind blows; A wind direction control unit configured to adjust a direction of the wind blowing toward the plurality of first impellers so that the plurality of first impellers do not break when a storm and a strong wind blow; It is provided rotatably in the third rotary rail, it characterized in that it comprises a current generating unit having a plurality of second impeller and rotates to generate power in the direction of the current.

The wind turbine may include a first rotation frame rotatably provided on the first rotation rail; A second rotating frame disposed to face the first rotating frame and rotatably provided on the second rotating rail; A plurality of support frames provided between the first rotation frame and the second rotation frame and spaced apart from each other; A first rotation shaft penetrating the plurality of support frames and rotatably supported; A plurality of first impellers provided on the first rotation shaft and each of which rotates by wind; A second rotating shaft rotatably supported through the second rotating frame so as to be perpendicular to the first rotating shaft; A steering blade provided on the first rotation frame and rotating the first rotation frame such that the plurality of first impellers face the wind blowing direction; A first power transmission unit for transmitting the rotational force of the first rotary shaft obtained by the rotation of the plurality of first impellers to the second rotary shaft; It is characterized in that it comprises a first power generation unit provided in the floating body and connected to the second rotation shaft, and generates power by the rotation of the second rotation shaft.

The first power transmission unit may include: a worm gear provided on the first rotation shaft to rotate according to rotation of the plurality of first impellers; It is characterized in that it comprises a worm wheel gear is provided at one end of the second rotation shaft to mesh with the worm gear and to receive the rotational force of the first rotation shaft.

In addition, the wind direction control unit, and provided between the first rotating frame and the second rotating frame, the first support is disposed facing the plurality of first impeller; A wind direction control plate provided on the first support to adjust a direction of wind blowing toward the plurality of first impellers; A rotary link having one end connected to the plate surface of the wind direction control plate and the other end hinged to the support frame to guide the wind direction control plate to be folded or unfolded on the first support; A second support provided between the first rotation frame and the second rotation frame to face the first support with the plurality of first impellers interposed therebetween; A braking plate that is hinged to the second support and rotates to be folded or unfolded, and is rotated and folded under wind resistance on a plate surface when a storm and a strong wind blow; One end is connected to the plate surface of the wind direction control plate, the other end is connected to the plate surface of the braking plate, the connection link portion for pulling or pushing the wind direction control plate according to the rotation of the braking plate to adjust the rotation of the wind direction control plate It is characterized by.

In addition, the connection link unit, the first connection link is connected to the plate surface of the wind direction control plate; A second connection link having one end connected to the plate surface of the brake plate and the other end connected to the first connection link; One end is connected to the connecting portion of the first and second connecting links, the other end is characterized in that it comprises a third connecting link hinged to the support frame.

In addition, the current generation unit, and a third rotating frame rotatably provided on the third rotary rail; A plurality of auxiliary support frames provided on a bottom of the third rotating frame and spaced apart from each other; A third rotation shaft penetrating the plurality of auxiliary support frames and rotatably supported; A plurality of second impellers provided on the third rotation shaft and rotating by currents; A fourth rotating shaft rotatably supported through the third rotating frame so as to be perpendicular to the third rotating shaft; An auxiliary steering blade provided on the auxiliary support frame and rotating the third rotation frame such that the plurality of second impellers are directed in the direction of the current; A second power transmission unit for transmitting the rotational force of the third rotational shaft obtained by the rotation of the plurality of second impellers to the fourth rotational shaft; And a second power generation unit provided in the floating body and connected to the fourth rotation shaft and generating power by the rotation of the fourth rotation shaft.

The second power transmission unit may include: an auxiliary worm gear provided on the third rotation shaft to rotate according to rotation of the plurality of second impellers; And an auxiliary worm wheel gear provided at one end of the fourth rotation shaft to be engaged with the auxiliary worm gear and to receive the rotational force of the third rotation shaft.

As described above, in the marine combined cycle apparatus according to the present invention by using the kinetic energy of the wind and the current as the energy source to perform the wind power generation and the current generation at the same time, the continuous power generation is possible to increase the amount of power generation.

In addition, when a storm and strong winds are blown by a typhoon, it is possible to block the wind toward the impeller to prevent damage to the impeller.

In addition, it is possible to move the floating body can be installed in a wide range of the sea.

1 is a perspective view showing the overall structure of the marine combined cycle power generation apparatus according to an embodiment of the present invention
Figure 2 is a bottom perspective view showing the overall structure of the marine combined cycle apparatus according to an embodiment of the present invention
Figure 3 is an exploded perspective view showing the overall structure of the marine combined cycle power generation apparatus according to an embodiment of the present invention
4 and 5 are cross-sectional view showing the overall structure of the marine combined cycle power generation apparatus according to an embodiment of the present invention
6 is a view showing the structure of the wind power generation unit in the marine combined cycle apparatus according to an embodiment of the present invention
Figure 7 is a perspective view showing the structure of the wind direction control unit in the marine combined cycle power generation apparatus according to an embodiment of the present invention
Figure 8 is a side view showing the structure of the wind direction control unit in the marine combined cycle power generation apparatus according to an embodiment of the present invention
9 is a view showing the structure of the current generation unit in the marine combined cycle power generation apparatus according to an embodiment of the present invention

 EMBODIMENT OF THE INVENTION Hereinafter, although the Example of this invention is described in detail, this invention is not limited to a following example, unless the summary is exceeded.

1 is a perspective view showing the overall structure of the marine combined cycle power generation apparatus according to an embodiment of the present invention, Figure 2 is a bottom perspective view showing the overall structure of the marine combined cycle power generation apparatus according to an embodiment of the present invention, Figure 3 is 4 and 5 are cross-sectional views illustrating the entire structure of an offshore combined cycle power generation apparatus according to an embodiment of the present invention.

As shown in Figures 1 to 5, the marine combined cycle apparatus according to an embodiment of the present invention is connected to the floating body 10 floating on the sea surface, the bottom of the floating body 10 is supported on the bottom Anchors 20, an upper frame 30 installed on the upper portion of the float 10, a lower frame 40 provided on the lower portion of the float 10, and a plurality of agents provided in the upper frame 30 The wind power generator 50 has a first impeller 59 and rotates toward the wind blowing direction and generates a plurality of first impellers 59 so that the plurality of first impellers 59 are not damaged by storms and strong winds. Wind direction control unit 80 for adjusting the direction of the wind blowing toward the) and the lower frame 40 is provided with a plurality of second impeller 117 and the current generation unit 110 to rotate and generate power in the direction of the current flow It includes.

The floating body 10 has a buoyancy force to float on the sea surface, and consists of a disk-shaped floating plate 11 and a plurality of floating cylinders 13 provided along the circumference of the bottom of the floating plate 11.

Here, the plurality of floating cylinders 13 are air cylinders floating on the sea surface and support the floating plate 11 so that the floating plate 11 is exposed above the sea surface.

The anchor 20 is connected to the chain 21 or wire from the bottom of the float 10, is supported on the sea bottom to moor the float 10 on the sea surface. 1 and 2, when a plurality of anchors 20 are provided in the floating body 10, the floating body 10 can be easily moored on the sea surface.

The upper frame 30 is installed on the upper portion of the floating body 10 serves to support the wind power generator (50).

The upper frame 30 includes a plurality of support bars 31 installed around the upper surface of the floating plate 11, a first rotating rail 33 supported by the plurality of support bars 31, and a first rotating rail. It consists of the support plate 35 supported by the several support bar 31 between the 33 and the floating plate 11, and the 2nd rotating rail 37 seated by the support plate 35. As shown in FIG.

Here, the first rotary rail 33 and the second rotary rail 37 are formed in a circular frame shape.

The lower frame 40 is installed at the bottom of the floating body 10 so as to be underwater, and serves to support the current generation unit 110.

The lower frame 40 is fixedly installed at the bottom of the floating body 10, and has a third rotary rail 41 forming a circular frame.

The wind power generator 50 is installed on the upper frame 30 so as to be rotatable on the first rotary rail 33 and the second rotary rail 37, and has a plurality of first impellers 59 and wind is blown. It develops by turning towards the direction of coming.

6 is a view showing the structure of the wind power generation unit in the marine combined cycle apparatus according to an embodiment of the present invention.

As shown in FIG. 6, the wind power generator 50 is disposed to face the first rotating frame 51 rotatably provided on the first rotating rail 33 and the first rotating frame 51. A second rotating frame 53 rotatably provided on the second rotating rail 37, a plurality of supporting frames 55 disposed between the first rotating frame and the second rotating frame and spaced apart from each other; A first rotational shaft 57 rotatably supported through the plurality of support frames 55, a plurality of first impellers 59 provided on the first rotational shaft 57 and rotated by wind, respectively, and a first A second rotating shaft 61 rotatably supported through the second rotating frame 53 so as to be perpendicular to the rotating shaft 57, and provided in the first rotating frame 51 and the plurality of first impellers 59. A steering blade 63 for rotating the first rotating frame 51 so that the air is directed in a direction in which the wind blows, and the plurality of first impellers 59. 1) is provided in the first power transmission unit 65 for transmitting the rotational force of the first rotation shaft 57 obtained by the rotation to the second rotation shaft 61, the floating body 10 is connected to the second rotation shaft 61 and It consists of the 1st power generation part 71 which generate | occur | produces by rotation of the 2 rotating shafts 61. As shown in FIG.

The first rotating frame 51 is a circular frame, which is rotatably seated on the first rotating rail 33. A plurality of rollers R for rolling along the first rotary rail 33 are provided at the bottom of the first rotary frame 51. Therefore, the first rotating frame 51 can be easily rotated in the first rotating rail (33).

The second rotating frame 53 is spaced below the first rotating frame 51 and seated on the second rotating rail 37. Here, the bottom of the second rotary frame 53 is provided with a plurality of rollers R rolling along the second rotary rail 37, so that the second rotary frame 53 is rotatable in the second rotary rail 37 To be seated.

The first rotation shaft 57 is horizontally disposed to be rotatably supported through the plurality of support frames 55.

The plurality of first impellers 59 are coupled to a plurality of axes on the first rotation shaft 57 and rotated by winds blowing from the sea, respectively.

The second rotation shaft 61 is vertically penetrated through the support frame 55, the second rotation frame 53, and the support plate 35 of the upper frame 30 in order to be rotatably supported by the bearing B. An upper end portion penetrating the frame 55 is disposed to face the first rotation shaft 57.

The steering blade 63 is installed perpendicular to the upper side of the first rotating frame 51 to rotate the first rotating frame 51 in the wind blowing direction, the wind by the rotation of the first rotating frame 51 The pair of first impellers 59 rotate in this blowing direction.

The first power transmission unit 65 is provided on the shaft of the first rotary shaft 57 and is provided on the upper end of the worm gear 67 and the second rotary shaft 61 to rotate in accordance with the rotation of the plurality of first impeller (59). It is composed of a worm wheel gear 69 is engaged with the worm gear 67 and receives the rotational force of the first rotation shaft (57).

Referring to the operation of the first power transmission unit 65 as described above, the plurality of first impeller 59 is rotated by the wind to rotate the first rotary shaft 57, the first rotary shaft 57 The worm gear 67 provided on the shaft meshes with the worm wheel gear 69 to rotate the worm wheel gear 69 so that rotation force is transmitted to the second rotation shaft 61.

The first power generation unit 71 is provided in the floating body 10 to receive the rotational force of the second rotary shaft 61 to generate electric power. That is, when the plurality of first impellers 59 rotate by the wind, the first power transmission unit 65 transmits the rotational force of the plurality of first impellers 59 to the second rotation shaft 61, thereby causing the second rotation shaft ( Receives the rotational force of 61) to generate power.

The first power generation unit 71 is provided in the floating body 10 and has a first generator 75 having a first generator shaft 73, and a first bevel gear 77 coupled to the first generator shaft 73. ) And a second bevel gear 79 coupled to the lower end of the second rotating shaft 61 to be engaged with the first bevel gear 77.

That is, when the second rotation shaft 61 is rotated by the first power transmission unit 65, the second bevel gear 79 is rotated so that the first bevel gear 77 meshed with the second bevel gear 79 is rotated. The rotating force of the first bevel gear 77 is transmitted to the first generator 75 through the first generator shaft 73 to generate power.

On the other hand, the wind direction control unit 80 adjusts the direction of the wind blowing toward the plurality of first impeller 59 so that the storm and the strong wind deviates the plurality of first impeller 59 when the storm and the strong wind is blowing by the typhoon. . That is, the direction of the wind blowing toward the pair of first impellers 59 is adjusted so that the first impellers 59 are not damaged by the storm and the strong wind.

7 is a perspective view showing the structure of the wind direction control unit in the marine combined cycle power generation apparatus according to an embodiment of the present invention, Figure 8 is a side view showing the structure of the wind direction control unit in the marine combined cycle power generation apparatus according to an embodiment of the present invention.

As shown in FIG. 7 and FIG. 8, the wind direction controller 80 is provided between the first rotating frame 51 and the second rotating frame 53 and faces the plurality of first impellers 59. And a wind direction control plate 85 provided on the first support 81, the first support 81 to adjust the direction of the wind blowing toward the plurality of first impellers 59, and one end of the wind direction control plate 85. Rotation link 87 and a plurality of first impeller connected to the plate surface and the other end is hinged to the support frame 55 to guide the wind direction control plate 85 to be folded or unfolded in the first support 81 A second support 89 and a second support 89 provided between the first rotation frame 51 and the second rotation frame 53 to face the first support 81 with the 59 interposed therebetween. Brake plate (91) rotates to be folded or unfolded by a hinge coupled to the plate, and rotates under the resistance of the wind to the plate surface when the storm and the strong wind blow. And, one end is connected to the plate surface of the wind direction control plate 85 and the other end is connected to the plate surface of the braking plate 91 to pull or push the wind direction control plate 85 in accordance with the rotation of the braking plate 91 wind direction control plate 85 Consists of a connection link portion 95 for adjusting the rotation.

Here, the first support 81 is formed with a first insertion groove 83 into which the steering blade 63 is inserted and coupled, and the second insertion groove into which the steering blade 63 is inserted and coupled to the brake plate 91. 93) is formed. Therefore, when the steering blade 63 rotates in the windy direction, the wind direction controller 80 also rotates together.

The wind direction control plate 85 is provided in pairs with the first insertion groove 83 therebetween in the first support 81, and is connected to the pair of rotary links 87, respectively, in the first support 81. Rotate to fold or unfold.

The connection link unit 95 is composed of a pair is connected to each of the pair of rotary link (87).

The connection link 95 has a first connection link 97 connected to the plate surface of the wind direction control plate 85, one end is connected to the plate surface of the braking plate 91 and the other end is connected to the first connection link 97. The second connecting link 99 is connected, one end is connected to the connecting portion of the first connecting link 97 and the second connecting link 99 and the third connecting link is hinged to the other end of the support frame 55 It consists of 101.

In such a configuration, as shown in FIG. 8A, a pair of wind direction control plates 85 are folded so that the plurality of first impellers 59 are rotated by wind, and in FIG. 8B. As described above, when the storm and the strong wind caused by the typhoon blow, the braking plates 91 and 83 are folded backward by the resistance of the wind, and thus the first connection link 97 and the second connection of the connection link unit 95 are folded. As the link 99 pulls the wind direction control plate 85, the wind direction control plate 85, which is folded at the first support 81, is expanded to block the storm and the strong wind blowing toward the plurality of first impellers 59. .

On the other hand, the current generation unit 110 is installed in the lower frame 40 rotatably provided on the third rotary rail 41, and has a plurality of second impeller 117 to rotate and generate power in the direction of the current .

9 is a view showing the structure of the current generation unit in the marine combined cycle apparatus according to an embodiment of the present invention.

As shown in FIG. 9, the current generation unit 110 is provided on the bottom of the third rotating frame 111 and the third rotating frame 111 rotatably provided on the third rotating rail 41, and mutually. A plurality of auxiliary support frames 113 disposed to be spaced apart from each other, a third rotation shaft 115 that is rotatably supported while passing through the plurality of auxiliary support frames 113, and is provided on the third rotation shaft 115 and in the sea current. A plurality of second impellers 117 rotated by each, a fourth rotating shaft 119 rotatably supported by vertically penetrating the third rotating frame 111 so as to be perpendicular to the third rotating shaft 115, and an auxiliary support. Auxiliary steering blade 121 is provided on the frame 113 and rotates the third rotating frame 111 so that the plurality of second impeller 117 is directed in the direction of the current flow, and the plurality of second impeller 117 is rotated A second power transmission unit 123 which transmits the rotational force of the third rotating shaft 115 obtained by the fourth rotating shaft 119, Provided on the fluid (10) connected to the fourth rotary shaft 119 and consists of a second power generation unit 129 that generated by the rotation of the fourth rotation shaft 119.

The third rotating frame 111 is a circular frame, rotatably seated on the third rotating rail 41. A plurality of rollers R rolling along the third rotary rail 41 are provided at the bottom of the third rotary frame 111.

The third rotation shaft 115 is horizontally disposed to be rotatably supported by the plurality of auxiliary support frames 113.

The plurality of second impellers 117 are coupled to the plurality of shafts of the third rotary shaft 115 and rotated by currents in the water, respectively.

The fourth rotating shaft 119 is vertically penetrated through the floating plate 11, the third rotating frame 111, and the auxiliary support frame 113 so as to be rotatably supported by the bearing B, and the auxiliary support frame 113. The lower end portion penetrating through the ()) is disposed to face the third rotation shaft 115.

The auxiliary steering blade 121 is installed on the bottom of the plurality of auxiliary support frame 113 to rotate the third rotating frame 111 in the direction of the current, the direction of the current by the rotation of the third rotating frame 111 As a result, the plurality of second impellers 117 rotate.

The second power transmission unit 123 is provided on the axis of the third rotary shaft 115 and the auxiliary worm gear 125 and rotates in accordance with the rotation of the plurality of second impeller 117, and the upper end of the fourth rotary shaft 119 It is made of an auxiliary worm wheel gear 127 is engaged with the auxiliary worm gear 125 and receives the rotational force of the third rotating shaft 115.

Referring to the operation of the second power transmission unit 123 as described above, the plurality of second impeller 117 is rotated by the current flow so that the third rotary shaft 115 is rotated, the third rotary shaft 115 of the The auxiliary worm gear 125 provided on the shaft is engaged with the auxiliary worm wheel gear 127 to rotate the auxiliary worm wheel gear 127 to transmit rotational force to the fourth rotation shaft 119.

The second power generation unit 129 is provided in the floating body 10 to receive the rotational force of the fourth rotating shaft 119 to generate electric power. That is, when the plurality of second impeller 117 rotates by the current current, the second power transmission unit 123 transmits the rotational force of the plurality of second impellers 117 to the fourth rotation shaft 119, and thus the fourth rotation shaft ( 119) is to receive the rotational force to generate power.

The second power generation unit 129 is provided in the floating body 10 and has a second generator 133 having a second generator shaft 131, and a first auxiliary bevel gear coupled to the second generator shaft 131 ( 135 and a second auxiliary bevel gear 137 coupled to the upper end of the fourth rotating shaft 119 to be engaged with the first auxiliary bevel gear 135.

That is, when the fourth rotating shaft 119 is rotated by the second power transmission unit 123, the second auxiliary bevel gear 137 is rotated to engage the first auxiliary bevel gear (137) engaged with the second auxiliary bevel gear 137 ( 135 is rotated, the rotational force of the first auxiliary bevel gear 135 is transmitted to the second generator 133 through the second generator shaft 131 to generate power.

Hereinafter, the operating state of the marine combined cycle apparatus according to the present invention configured as described above will be described with reference to FIGS.

The wind power generation unit 50 installed on the upper portion of the floating body 10 is generated by wind pressure, and the current generation unit 110 installed at the bottom of the floating body 10 is positioned by water current so as to be located in the water.

Here, the plurality of anchors 20 are connected to the bottom of the float 10 by a chain 21 or a wire so that the float 10 is moored on the sea surface and is supported on the sea bottom.

First, the development process of the wind power generator 50 is as follows.

When the wind blows from the sea, the first rotary frame 51 is rotated in the direction of the wind by the steering blade 63 so that the plurality of first impellers 59 are arranged to receive the wind.

When the plurality of first impellers 59 are rotated by the wind, as the first rotation shaft 57 is rotated, the rotational force of the pair of first rotation shafts 57 is increased by the first power transmission unit 65. 61, the rotational force of the second rotary shaft 61 is transmitted to the first power generation unit 71 to generate power.

At this time, the wind direction control plate 85 is folded in the first support 81, the wind can be introduced into the plurality of first impeller (59).

On the other hand, when the storm and strong winds caused by the typhoon blows, the braking plate 91 is folded backward by the resistance of the wind, the first link link 97 and the second link link 99 of the link link portion 95 By pulling the rotary link 87, the wind direction control plate 85 folded in the first support 81 is expanded to block storms and strong winds blowing toward the plurality of first impellers (59).

Therefore, it is possible to prevent the plurality of first impellers 59 from being damaged by the storm and the strong wind.

Next, the development process of the current generation unit 110 is as follows.

The third rotating frame 111 is rotated in the direction of the current by the auxiliary steering blade 121 in the water so that the plurality of second impellers 117 are rotated by the current.

When the plurality of second impeller 117 rotates due to the current flow, as the third rotation shaft 115 is rotated, the rotational force of the third rotation shaft 115 is transmitted to the fourth rotation shaft 119 by the second power transmission unit 123. Is transmitted, the power generated by the rotational force of the fourth rotating shaft 119 is transmitted to the second power generation unit (129).

As described above, in the marine combined cycle apparatus according to the present invention by using the kinetic energy of the wind and the current as the energy source to perform the wind power generation and the current generation at the same time, the continuous power generation is possible to increase the amount of power generation.

In addition, when a storm and strong winds are blown by a typhoon, it is possible to block the wind toward the impeller to prevent damage to the impeller.

In addition, it is possible to move the floating body can be installed in a wide range of the sea.

As those skilled in the art to which the present invention pertains, the present invention may be modified in various ways without departing from the spirit of the present invention. .

10: floating body 20: anchor
30: upper frame 33: the first rotating rail
37: second rotating rail 40: lower frame
41: third rotary rail 50: wind power generation unit
51: first rotation frame 53: second rotation frame
55: support frame 57: first axis of rotation
59: first impeller 61: second rotating shaft
63: steering wing 65: first power transmission unit
67: worm gear 69: worm wheel gear
71: first power generation unit 80: wind direction control unit
81: first support 85: wind direction control plate
87: rotary link 89: second support
91: braking plate 95: link portion
97: first connection link 99: second connection link
101: third link 110: current generation
111: third rotation frame 113: auxiliary support frame
115: third rotary shaft 117: second impeller
119: fourth rotating shaft 121: auxiliary steering wing
123: second power transmission unit 125: auxiliary worm gear
127: auxiliary worm wheel gear 129: second power generation unit

Claims (7)

A float having buoyancy to float on sea level;
An anchor connected to the bottom of the float to be supported by the sea bottom so that the float is moored to the sea surface;
An upper frame installed at an upper portion of the floating body so as to be positioned in the water phase, and having a first rotating rail and a second rotating rail spaced apart from each other in a circular frame;
A lower frame installed under the floating body so as to be underwater, and having a third rotary rail forming a circular frame;
A wind power generation unit rotatably provided on the first rotating rail and the second rotating rail and having a plurality of first impellers and rotating in a direction in which a wind blows;
A wind direction control unit configured to adjust a direction of the wind blowing toward the plurality of first impellers so that the plurality of first impellers do not break when a storm and a strong wind blow;
It is provided rotatably on the third rotary rail, the marine combined cycle apparatus comprising a current generator having a plurality of second impeller and rotates to generate power in the direction of the current. The method of claim 1,
The wind power generation unit,
A first rotating frame rotatably provided on the first rotating rail;
A second rotating frame disposed to face the first rotating frame and rotatably provided on the second rotating rail;
A plurality of support frames provided between the first rotation frame and the second rotation frame and spaced apart from each other;
A first rotation shaft penetrating the plurality of support frames and rotatably supported;
A plurality of first impellers provided on the first rotation shaft and each of which rotates by wind;
A second rotating shaft rotatably supported through the second rotating frame so as to be perpendicular to the first rotating shaft;
A steering blade provided on the first rotation frame and rotating the first rotation frame such that the plurality of first impellers face the wind blowing direction;
A first power transmission unit for transmitting the rotational force of the first rotary shaft obtained by the rotation of the plurality of first impellers to the second rotary shaft;
And a first power generation unit provided on the floating body and connected to the second rotation shaft and generating power by the rotation of the second rotation shaft. The method of claim 2,
The first power transmission unit,
A worm gear provided on the first rotation shaft to rotate according to rotation of the plurality of first impellers;
And a worm wheel gear provided at one end of the second rotation shaft to mesh with the worm gear and to receive the rotational force of the first rotation shaft. The method of claim 2,
The wind direction control unit,
A first support provided between the first rotating frame and the second rotating frame and disposed to face the plurality of first impellers;
A wind direction control plate provided on the first support to adjust a direction of wind blowing toward the plurality of first impellers;
A rotary link having one end connected to the plate surface of the wind direction control plate and the other end hinged to the support frame to guide the wind direction control plate to be folded or unfolded on the first support;
A second support provided between the first rotation frame and the second rotation frame to face the first support with the plurality of first impellers interposed therebetween;
A braking plate that is hinged to the second support and rotates to be folded or unfolded, and is rotated and folded under wind resistance on a plate surface when a storm and a strong wind are blown;
One end is connected to the plate surface of the wind direction control plate, the other end is connected to the plate surface of the braking plate, the connection link portion for pulling or pushing the wind direction control plate according to the rotation of the braking plate to adjust the rotation of the wind direction control plate Marine combined cycle power generation apparatus, characterized in that. The method of claim 4, wherein
The link portion,
A first connection link connected to the plate surface of the wind direction control plate;
A second connection link having one end connected to the plate surface of the brake plate and the other end connected to the first connection link;
One end is connected to the connecting portion of the first connecting link and the second connecting link, and the other end comprises a third connecting link which is hinged to the support frame. The method of claim 1,
The current generation unit,
A third rotating frame rotatably provided on the third rotating rail;
A plurality of auxiliary support frames provided on a bottom of the third rotating frame and spaced apart from each other;
A third rotation shaft penetrating the plurality of auxiliary support frames and rotatably supported;
A plurality of second impellers provided on the third rotation shaft and rotating by currents;
A fourth rotating shaft rotatably supported through the third rotating frame so as to be perpendicular to the third rotating shaft;
An auxiliary steering blade provided on the auxiliary support frame and rotating the third rotation frame such that the plurality of second impellers are directed in the direction of the current;
A second power transmission unit for transmitting the rotational force of the third rotational shaft obtained by the rotation of the plurality of second impellers to the fourth rotational shaft;
And a second power generation unit provided on the floating body and connected to the fourth rotation shaft and generating power by the rotation of the fourth rotation shaft. The method of claim 6,
The second power transmission unit,
An auxiliary worm gear provided on the third rotation shaft to rotate according to rotation of the plurality of second impellers;
And an auxiliary worm wheel gear provided at one end of the fourth rotation shaft to be engaged with the auxiliary worm gear and receiving rotational force of the third rotation shaft.

Images