KR20100129515A - A wind generator under the bridge - Google Patents

Abstract

PURPOSE: A wind generator using wind generated between a bridge and a pier is provided to effectively deal with strong wind by installing an additional vane. CONSTITUTION: A wind generator(10) using wind generated between a bridge and a pier comprises generator fixing frames, vane units(15), vane generators(16), a generating device(18), and generators(19). The generator fixing frames fix wind generator between piers(12) of a bridge(11). The vane units are rotated by wind from the side surfaces of the piers. The vane generators power the vane units. The generating device is rotated by wind from the front surface of the piers. The generators power the generating device.

Description

Wind generators using cold wind between bridge piers {A Wind Generator under the Bridge}

The present invention relates to a wind power generator for converting the rotational force rotated by the wind into electrical energy, in particular, is installed between the piers provided on the lower side of the bridge to rotate using a strong wind generated constantly between the piers and piers Wind power generator using the cold wind between the bridge piers that converts the rotational force generated by rotating the blades into electrical energy to supply electric power for charging road facilities such as street lamps and road signs and electric vehicles. It is about.

In general, a wind power generator converts wind power into rotational power and uses the generated rotational power to generate induction electricity by using a generator. It is a generator that uses the power of wind to produce energy.

However, such a conventional wind power generator can produce the necessary electricity without polluting the environment, such as thermal power generation or nuclear power generation, but the amount of power generated is very low and the efficiency of power generation is considerably insufficient compared to the huge installation cost. I'm staying.

As such, wind-generated generators spend huge budgets on roads and mountains, and are less valuable in the long run, and are driven by the speed of the vehicle passing through the tunnel to make better use of everyday urban or natural environments at minimal cost. The range of application and technology level have appeared in various ways, such as the generation of electric energy by using wind power generated or wind of general buildings or the winds of plains and beaches, and the production efficiency of electric energy is also gradually improving. .

Among such wind generators, a method or an apparatus for producing electric power using a bone wind generated between each of the bridges provided on the lower side of the bridge, in particular, has appeared and is used in various ways. This is caused by the pier or each building where wind gusts are generated between bridges of bridges installed on land and at sea, or in urban alleys with skyscrapers. These winds are very strong in wind power, and wind power generation using them is highly efficient. Because it is.

Therefore, as a power generation system for the wind power generation using the bone breeze of the conventional bridge is known as the 'wind power generation system for the bridge module unit applied' Patent Publication No. 2006-0084686, and also as a power generation device of the Patent Publication No. 2002-0024995 The production of human-connected wind turbines is known, and a brief summary of their structure is as follows.

As shown in FIG. 7, the 'window power generation system 50 for a unit module is applied' includes an electric facility 52 installed around a bridge 51 crossing a river, and the bridge 51. It is composed of a unit power generation module 53 installed at the lower side of the electric energy generating unit 53 and a management system 54 for supplying the electric power generated from the unit power generation module 53 to the electrical facility 52, the unit The power generation module 53 controls a small wind power generator 531, a wind speed sensor 532 and a rectifier 533 for detecting wind speed, a storage 534 for storing power, and an operation of the unit power generation module 53. The control device 535 is configured.

The conventional wind power generation system for bridges 50 configured as described above rectifies the power generated in the wind power generator 531 through a rectifier 533, converts it into direct current, stores it in the storage 534, and whenever necessary. It is transmitted to the management system 54 and supplied to each electric facility and used.

In addition, the production of the human-connected wind turbine 60 is blown from the front and side, and the generator fixed body 61 for holding the wind turbine 60 fixed, as shown in FIG. Wind baffle plate 62 to collect the coming wind, the wind blower plate 63 functioning as a blade rotated by the blowing wind, and the wind baffle plate 62 and the wind blower plate 63 can be rotated The rotating shaft 64 to be installed, the generator 65 installed on the rotating shaft 64 to convert rotational force into electrical energy, and the rotating shaft 64 are firmly fixed to the generator fixing body 61. It is composed of a mounting support 66 for fixed mounting.

The human-connected wind turbine generator 60 configured as described above, when the force of the blowing wind rotates the wind turbine plate 63, the rotation force rotates the pivot shaft 64, and then the electric power from the generator 65. Will be able to produce. The electric power thus produced is conveniently utilized for street lamps and other electrical facilities, and the conventional wind power generator 60 may be installed and used in windy beaches or islands and mountain ridges and wide valleys.

However, the wind power generator as described above applies the general wind power generator, not the structure of the power generation device using the cold wind between the bridges provided on the lower side of the bridge 'window power generation system 50 to which the unit module is applied. The present invention relates to a system for controlling an electric facility by using generated electric power. The wind power generator 60 also relates to a power generator having a blade that is rotated according to the intensity of the blowing wind, that is, a windshield uniformly fixed. There is a problem in that it does not respond appropriately to the intensity of the blowing wind according to the specificity of the.

Accordingly, the present invention has been made to solve the above problems, by utilizing the specificity of the bone wind generated between the pier to drive the joint gear unit and drive it to adjust the angle of the blade according to the strength of the bone wind blowing in front Equipped with a sensor to detect the strength of the motor and the wind, the joint gear part is reduced in strong winds such as a typhoon to decrease the angle of the blade to weaken the resistance. The wind blowing by installing a separate vane (vane) to cope with the strength of the wind strength and to respond effectively to the wind blowing on the side by making the most of the characteristics of the wind to improve the power production dramatically There is a windstorm between the piers of the bridge To provide a wind turbine it is an object.

Wind power generator using the cold wind between the bridge piers of the present invention for achieving the above object is provided between the bridge 12 under the bridge 11 is fixed to the generator fixed frame for installing the wind generator 10 13 and the vane rotating shaft 14 and the vane fixing shaft 14a are provided on both sides of the power generating apparatus fixing frame 13 so that the vane rotating shaft 14 and the vane fixing shaft 14a can be rotated by the wind blowing from the side of the bridge 12. A vane generator 15 having a vane generator 15 connected to the vane device 15 to generate electric power by charging the rotational force of the vane device 15 with electrical energy, and the generator fixing frame 13. A power generation device 18 having a power generation rotation shaft 17 and a power generation fixed shaft 17a so as to be installed at a lower side of the power source so as to be rotated by wind blowing from the front of the pier 12, and the power generation device 18 Is installed on both sides of the power generator 18 Doedoe configure the power to the generator 19 to develop the charge into electric energy;

The power generator 18 is inserted into the power generating shaft 17, the cylindrical body 181 is rotated, and the main blade 182 is fixed to the circumferential surface of the cylindrical body 181 at a fixed interval to resist the wind ), And an extension blade 183 installed to be pivotally connected to an end of the main blade 182, and an auxiliary blade 184 installed and fixed between the main blades 182 to resist wind. Characterized in that made.

Therefore, the wind power generator using the cold wind between the bridge piers in accordance with the present invention weakens the resistance by bending the joints in small winds such as typhoons with strong winds, reducing the angle of the blades. Increasing the resistance, the wind blowing to the side by installing a separate vane (vane) to cope with the strength of the wind strength and to effectively respond to the wind blowing from the side by making the most of the characteristics of the bone wind There is an advantage that can dramatically improve the production.

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

1 is a state diagram in which a wind turbine is installed using a gust of wind between the bridge piers according to the present invention,

Figure 2 is a perspective view of the wind power generator using the cold wind between the bridge piers according to the invention,

3 is a cross-sectional state view of the main portion of the wind power generator using the cold wind between the bridge piers according to the present invention,

Figure 4 is a side view of the main portion of the wind power generator using the cold wind between the bridge piers according to the present invention,

Figure 5 is a perspective view of the main portion of the wind power generator using the cold wind between the bridge piers according to the present invention,

Figure 6 is a schematic state diagram provided with a rotary device installed in the wind turbine using the cold wind between the bridge piers in accordance with the present invention,

7 and 8 is a state diagram of a conventional wind power generator.

As shown in FIG. 1 and FIG. 2, the wind turbine 10 using the bone breeze between the bridge piers according to the present invention is provided between the wind turbine 10 between the piers 12 provided on the lower side of the bridge 11. Power plant fixing frame (13) for installing),

Vanes 15 provided on both sides of the power generator fixing frame 13 and having a vane rotating shaft 14 and a vane fixing shaft 14a so as to be rotated by wind blowing from the side of the pier 12. )Wow,

A vane generator 16 connected to the vane device 15 to generate electric power by charging the rotational force of the vane device 15 with electric energy;

The generator 18 is installed on the lower side of the generator fixing frame 13 and has a power generating rotation shaft 17 and the power generating fixed shaft 17a to be rotated by the wind blowing from the front of the pier 12. )Wow,

Is installed on both sides of the generator 18 is composed of a generator 19 for generating power by charging the rotational force of the generator 18 with electrical energy;

The power generating device 18 is connected to the power generating rotation shaft 17, the cylindrical body 181 is rotated, and the main blade (main blade which is installed and fixed at a predetermined interval on the circumferential surface of the cylindrical body 181 to resist the wind (main) Blade, 182, the extension blade 183 is connected to be installed rotatably at the end of the main blade 182 and the auxiliary blade is installed between each of the main blades 182 fixed to increase the wind resistance ( 184) is configured to rotate while resisting the wind blowing from the front.

Here, as shown in FIGS. 3 and 4, an end portion of the main blade 182 is provided with a spline driving gear 185, and the spline driving gear 185 is rotated by the driving motor 20. And a spline gear portion 187 engaged with the spline driving gear 185 at one end of the extension blade 183 at both ends of the connecting shaft 188. It is equipped with installation.

In addition, the driving motor 20 is provided with a wind pressure sensor (21) connected to detect the strength of the wind, that is, strong winds such as breezes and typhoons to rotate the forward and reverse.

In addition, the auxiliary blade 184 is connected to the auxiliary extension blade 184a which is rotatable at the end thereof similarly to the main blade 182, and the end of the auxiliary blade 184 3 and 4 As shown in the figure, the auxiliary sprinkler drive gear part 184b is provided, and the auxiliary spline drive gear part 184b is rotatable by the auxiliary drive shaft 184d rotated by the auxiliary drive motor 184c. Also, at one end of the auxiliary extension blade 184a, auxiliary spline gear parts 184e engaged with the auxiliary spline driving gear part 184b are provided at both ends of the auxiliary connecting shaft 184f.

In addition, the auxiliary driving motor 184c is provided with an auxiliary wind pressure sensor 184g for detecting the strength of the wind, that is, strong winds such as breezes or typhoons, and forward and reverse rotation thereof.

Therefore, when a strong wind such as a typhoon blows, when the wind pressure sensor 21 detects this and drives the driving motor 20, the spline driving gear part 185 rotates in the direction of an arrow A, and then the spline As the spline gear part 187 engaged with the drive gear part 185 is rotated together with the connecting shaft 188, the extension blade 183 is rotated in the direction of the arrow B so that the main blade 182 and the extension are extended. The angle of the blade 183 becomes narrow.

In addition, when a strong wind such as a typhoon blows, the auxiliary wind pressure sensor 184g also detects this and drives the auxiliary driving motor 184c. Then, the auxiliary spline driving gear part 184b is rotated in the direction of an arrow A. As the auxiliary spline gear part 184e engaged with the auxiliary sprinkler driving gear part 184b is rotated together with the auxiliary connecting shaft 184f, the auxiliary extension blade 184a is rotated in the direction of the arrow B and the auxiliary The angle between the blade 184 and the auxiliary extension blade 184a is narrowed.

By operating in this way, the main blade 182 and the extension blade 183 and the auxiliary blade 184 and the auxiliary extension blade 184a are subjected to a strong wind pressure, that is, less resistance to be safely protected from damage or breakdown, etc. It becomes possible.

And when the wind strength is not a strong wind breeze blows on the contrary to the wind pressure sensor 21 detects this to drive the drive motor 20 in reverse and accordingly the spline drive gear unit 185 And the spline gear part 187 are rotated in directions opposite to the direction of the arrow, respectively, so that the angles of the main blade 182 and the extended blade 183 are widened. In this case, the auxiliary blade 184 and the auxiliary extension blade 184a are also made in the same manner as the operation when the breeze blows the wind strength is not strong wind.

Therefore, although the wind strength is a breeze, the rotational force is increased by receiving a lot of resistance of the blowing wind, thereby improving the production efficiency of electric energy.

In addition, one side of the main blade 182, the extension blade 183 and the auxiliary blade 184, that is, the surface receiving the wind resistance, as shown in Figure 5, receives more resistance to the blowing wind A plurality of wind pockets 189 are formed, and both sides of the wind pockets 189 are provided with concave grooves 189a in the lower side to further receive air resistance of blowing wind. . Therefore, the rotational force of the power generator 18 is doubled by the wind pocket 189 and the concave groove 189a, thereby improving the production efficiency of electric energy. In addition, as described above, the auxiliary extension blade 184a may be formed with the wind pocket 189 and the concave groove 189a.

In this case, by attaching a light emitting material 190 such as an LED or a reflective material to the wind pocket 189, an additional useful value that can be utilized as a warning light or a lighting lamp may be obtained at night.

In addition, as shown in Figure 6, the wind turbine generator 10 using the wind blow between the bridge piers according to the present invention can rotate the wind turbine generator 10 to the upper end of the generator fixing frame 13 The device 22 can be installed and configured. This is fixedly mounted on the lower surface of the bridge (11) and then installed on the rotary device 22 so that the wind turbine 10 is rotatable by blowing the wind from the rear or other side rather than the front When the wind generator 10 is rotated by 180 degrees or at an angle that can hit the wind as much as possible to operate the wind generator 10 can be efficiently managed.

The wind turbine generator 10 using the wind blow between the bridge piers of the present invention configured as described above rotates the vane device 15 and the power generator 18 by using the strong wind blown between the bridge piers. By using the rotational force that is used to build the transmission and distribution system of the electrical energy produced by the vane generator 16 and the generator 19 to supply to the electrical facilities of the bridge to utilize and to prevent freezing generated from the bridge deck In addition, the utility of the electric vehicle for charging the electric vehicle, such as an electric vehicle or a prime mover vehicle can be made in a variety of applications.

1 is a state diagram in which a wind turbine is installed using a gust of wind between the bridge piers according to the present invention,

Figure 2 is a perspective view of the wind power generator using the cold wind between the bridge piers according to the invention,

3 is a cross-sectional state view of the main portion of the wind power generator using the cold wind between the bridge piers according to the present invention,

Figure 4 is a side view of the main portion of the wind power generator using the cold wind between the bridge piers according to the present invention,

Figure 5 is a perspective view of the main portion of the wind power generator using the cold wind between the bridge piers according to the present invention,

Figure 6 is a schematic state diagram provided with a rotary device installed in the wind turbine using the cold wind between the bridge piers in accordance with the present invention,

7 and 8 is a state diagram of a conventional wind power generator.

<Code Description of Main Parts of Drawing>

10: wind power generator 11: bridge 12: pier 13: power generator fixed frame 14: vane coaxial

14a: vane fixed shaft 15: vane device 16: vane generator 17: power generation shaft

17a: power stationary shaft 18: generator 19: generator 20: drive motor

21: Wind pressure sensor 22: Rotating device 181: Cylindrical body 182: Main blade

183: extended blade 184: secondary blade 189: wind pocket 190: light emitting material

185: spline drive gear 186: drive shaft 187: spline gear 188: connecting shaft

184a: Auxiliary extension blade 184b: Auxiliary spline drive gear 184c: Auxiliary drive motor

184d: Auxiliary drive shaft 184e: Auxiliary sprocket gear 184f: Auxiliary connecting shaft

184g: Auxiliary wind pressure sensor

Claims (6)

In the wind power generator 10 to generate power by using the wind blow formed between the bridges provided in the lower portion of the bridge, The wind generator 10 is provided between the bridge 12 under the bridge 11 is provided with a generator fixed frame 13 for fixing the wind generator 10, and Vanes 15 provided on both sides of the power generator fixing frame 13 and having a vane rotating shaft 14 and a vane fixing shaft 14a so as to be rotated by wind blowing from the side of the pier 12. )Wow, A vane generator 16 connected to the vane device 15 to generate electric power by charging the rotational force of the vane device 15 with electric energy; The generator 18 is installed on the lower side of the generator fixing frame 13 and has a power generating rotation shaft 17 and the power generating fixed shaft 17a to be rotated by the wind blowing from the front of the pier 12. )Wow, Is installed on both sides of the generator 18 is composed of a generator 19 for generating power by charging the rotational force of the generator 18 with electrical energy; The power generation device 18 is a cylindrical body 181 is inserted into the rotating shaft 17 and rotated, the main blade 182 is fixed to be installed at regular intervals on the circumferential surface of the cylindrical body 181, and the main Wind generator using a breeze between the piers of the bridge, characterized in that consisting of an extension blade (183) that is connected to be installed rotatably at the end of the blade (182). According to claim 1, wherein the main blade 182 is provided with a spline drive gear 185 is rotated by the drive motor 20, one end of the extension blade 183 is the spline drive gear portion Wind turbines using the blast between the piers of the bridge, characterized in that the spline gear portion 187 is engaged with the rotation (185) is provided. According to claim 1, wherein the auxiliary blade 184 is further provided between the main blade 182 and the main blade 182, the auxiliary extension blade 184a is installed at the end of the auxiliary blade 184 to be rotatable. One end of the auxiliary blade 184 is provided with an auxiliary spline driving gear portion 184b rotated by the auxiliary driving motor 184c, and one end of the auxiliary extension blade 184a is provided with the auxiliary spline driving gear portion ( 184b) a wind power generator using the cold wind between the bridge piers, characterized in that the secondary spline gear portion (184e) is engaged with the rotation. According to claim 1, The main blade 182 and the side of the extended blade 183 is provided with a wind pocket 189, both sides of the inside of the wind pocket 189 concave grooves to receive a lot of air resistance ( 189a) is formed, and the wind pocket 189 is a wind generator using a cold wind between the bridge piers, characterized in that the LED or the light emitting material 190 is attached to the installation. The wind turbine generator according to claim 1, wherein the upper side of the generator fixing frame (13) is further provided with a rotating device (22) capable of rotating it. According to claim 3, The side of the auxiliary blade 184 is provided with a wind pocket 189, On both sides of the inside of the wind pocket (189) concave groove 189a is formed to receive a lot of air resistance, and The wind pocket 189 is a wind power generator using the cold wind between the bridge pier, characterized in that the LED or light emitting material 190 is attached to the installation.

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