KR101282046B1 - Generation system using Solar modules and Wind power generator, The Manufacturing methods - Google Patents

Abstract

The present invention relates to a hybrid power generation system of a hybrid structure using a multi-spherical solar cell module and a Savonius vertical axis wind power generator and a method for manufacturing the same. This is to maximize the efficiency.
The hybrid generator is a vertical axis-type wind power generation unit consisting of a plurality of blades, the solar power generation unit is installed in the upper position of the wind power generation unit and a plurality of solar cell modules are connected in series with a plurality of cells in series, and The wind power generator is installed in the lower portion, the photovoltaic power generation unit is installed in the upper frame, the controller for charging and supplying the electric energy generated in the wind power generator and the solar power generation unit, and the battery is charged with electricity through the controller Consists of the effect of avoiding deterioration of shadows and shadows, preventing a rapid decrease in power generation efficiency, and maximizing power generation through the combined development of solar and wind power.

Description

Hybrid urban hybrid power generation system using multi-faceted multi-faceted solar cell module and noise-free low-speed Savonius wind power generator and its manufacturing method {Generation system using Solar modules and Wind power generator, The Manufacturing methods}

The present invention relates to a hybrid power generation system, and more particularly, to generate high-efficiency power generation and to respond to shadows and shadows in a cloud cloud and cloudy day non-directional scattering, and is not affected by wind direction and noise is generated. The present invention relates to an urban hybrid power generation system in which a vertical low speed savonius wind turbine generator for a silent wind power generation without a wind turbine is composed of a complex structure.

In general, a generator using renewable energy includes a solar flat panel module generator that converts light energy of sunlight into electric energy and a wind power generator that converts wind power into electrical energy by rotating a bar blade using wind.

The solar cell module of the conventional hybrid power generation system was used as a flat panel solar cell module was installed so that the direction of the solar cell module facing south or south middle altitude to maximize the daylighting time. However, in this method, the power generation efficiency is drastically reduced when the sunlight is out of the angle of light of the flat panel module. In order to solve the above problems, a photovoltaic power generation system using a yaw joint structure of an automatic solar tracking method has been invented, but the method has limitations in securing durability and space of joints and a yaw structure and requires periodic maintenance.

As illustrated in FIG. 7, in the conventional hybrid power generation system, a horizontal shaft wind power generator 502 is coupled to an upper portion thereof, and a solar flat panel module 501 is coupled to a lower portion thereof. The solar flat panel module 501 may be installed in a place where shadows and shadows generated by the horizontal axis wind power generator 502 coupled to the upper part are generated, such as shadows and shadows such as a lot of buildings or a lot of trees. In case of direct sunlight, the power generation of flat panel module due to sunlight decreases drastically, and in case of severe summer, the solar cell module is whitened or yellowed due to burned out or deteriorated cells due to short phenomenon of shadow and shadow. The life span of the solar cell module is rapidly reduced and the ribbon line is broken. In addition, due to the large area of the plane is subjected to a strong resistance due to wind pressure has a problem that the connection portion of the solar cell module structure is broken. Therefore, the solar cell is very sensitive to the sunlight light condition, so the shadow and the shadow have a decisive influence on the increase and decrease of the power generation output, so the method of absolutely avoiding the place where the shadow and the shadow is generated has to be devised.

In addition, the wind generator is coupled to the upper part of the solar cell module to cause shadow shading caused by sunlight, which hinders the flat solar cell power generation and the horizontal axis wind power generator is used. Due to the wind direction which is generated and changes frequently, the power generation unit including the blade has to rotate continuously according to the wind direction. Due to this, there is a problem that damage is caused by extreme noise and the durability of the rotating part included in the power generation unit is reduced, causing a failure.

Therefore, the present invention has been made to solve the above problems, the object of the wind turbine and the multi-sphere solar module coupled to the upper portion unobstructed by the surrounding shadows and shadows of the Savonius wind turbine with high wind drag It is a complex structure that enables high-efficiency power generation in response to multi-directional cloud clouds, non-directional scattering solar radiation, and shadows and shadows. The purpose of the present invention is to provide a highly efficient urban hybrid generator with a low speed Savonius composite structure with a large wind speed drag on the vertical axis that enables the structure and a three-stage multi-stage configuration of the blade to prevent rotational noise.

In order to achieve the above object, the present invention, the lower stage is positioned so that the wind power generation unit is coupled to a plurality of supports coupled to the end and the upper coupled to the upper frame, the plurality of solar cell module packages coupled to the upper portion of the frame A multi-directional photovoltaic unit, a harvesting circuit for collecting electrical energy generated in the photovoltaic unit in parallel, a generator coupled to the lower part of the frame, a shaft extending from the vertical axis of rotation, And a wind turbine including a plurality of rotating plates vertically coupled and a plurality of blades formed and coupled to each other, and a controller configured to charge and control the electric energy generated by the photovoltaic unit and the wind turbine. Characterized in that.

The present invention is not restricted by the installation place, and due to the multi-phase power generation in each of a plurality of modules configured in multi directions, power generation is reduced due to shadows and shadows, and high efficiency power generation can be achieved in power generation. Compared with the flat panel solar cell module of the same class, the efficiency is increased by about 38%, and there is no need of a separate place considering the wind direction and noise, and the low friction vertical shaft blade does not generate air friction noise due to the rotation. It is effective to provide.

1 is a configuration diagram of a hybrid power generation system.
2 is a front view of a hybrid power generation system.
3 is a schematic view of the solar power generation unit.
Figure 4 is an illustration of the power generation principle of the photovoltaic unit and harvesting circuit
5 is a connection diagram with a junction box of a solar cell module package.
6 is an exploded structure diagram of the wind power generation unit.
Figure 7 is an illustration of the shadow and shadow correspondence of the conventional hybrid power generation system.
8 is an exemplary view of the shadow and shadow corresponding to the photovoltaic unit according to the present invention.
9 is an exemplary view of the shadow and shadow corresponding to the photovoltaic unit according to the present invention.

Hereinafter, an urban hybrid power generation system having a complex structure using a multi-directional power generation multi-sphere solar cell module and a low noise low-speed Savonius wind power generator according to the present invention and a method of manufacturing the same will be described in detail with reference to the accompanying drawings.

2 or 6, the frame 40 has a lower base 402 is positioned so that the wind power generation unit 20 is coupled to the lower portion, the end of the lower base 402 as shown in FIG. A plurality of support 403 is coupled, the upper support 401 is coupled so that the photovoltaic unit 10 is coupled to the upper portion of the support 403. The generator 201 is positioned on the lower base 402, the shaft 202 extends on a vertical rotation shaft formed in the generator 201, and a plurality of rotating plates 203 are horizontally disposed on the shaft 202. Is coupled, a plurality of blades 204 formed in a curved surface between the plurality of rotating plate 203 configured to rotate under drag, and a plurality of spacing 207 is coupled between the plurality of rotating plate 203 And maintain the interval of the rotating plate 203 to be constant, and the guide hole 206 is formed in the rotating plate 203, inserted into the guide hole 206 and the spacer 207 to the wind power generation unit 20 Wind power generation unit 20 including a guide 205 to prevent the flip is coupled. In addition, the photovoltaic unit 10 is coupled to the upper stage 401 of the frame 40.

Referring to FIG. 3, the photovoltaic power generation unit 10 includes a plurality of solar cell module packages 101 configured in a fan shape in multiple directions, and the solar cell module package 101 includes a plurality of solar cell modules. It consists of 102, the solar cell module 102 is composed of a plurality of solar cells (103). The plurality of solar cells 103 included in the single solar cell module package 101 are connected in series to the ribbon line 104, and the generated electrical energy is transmitted to the harvesting circuit 121.

In addition, referring to FIG. 5, a plurality of junction boxes 131 are coupled to the upper and lower portions of the ribbon line 104, which is an entry and exit line of the solar cell module 102, and through the junction box 131. The ribbon line 104 between the battery modules 102 is connected. A wire inlet 132 is formed at an upper end or a lower end of the junction box 131, and a power line 133 is connected through the wire inlet 132. In addition, the hinge 134 is coupled to one side of the solar cell module package 101 is configured to open and close a single solar cell module package 101 as a door if necessary. The solar cell module package 101 has a fan-shaped upper solar cell module package 105 and a fan-shaped lower solar cell module package 106 are configured in a fan shape.

Referring to FIG. 1, the electrical energy generated by each solar cell module package 101 included in the photovoltaic unit 10 is transmitted to the harvesting circuit 121, and the control unit in the harvesting circuit 121. It is transmitted to the controller 301 included in 30.

In addition, the electric energy generated by the wind power generator 20 is also transmitted to the controller 301. The electric energy is charged into the storage battery 302 under the control of the controller 301, and the temperature adjusting means 303 is controlled to maintain the temperature required by the storage battery 302. In addition, when output is required, the electric energy stored in the storage battery 302 is output through the control of the controller 301.

8 or 9, when the sun 504 is obscured by the clouds 505 or when shadows and shades 503 are generated on the surface of the photovoltaic unit 10 by wires and trees, etc. The solar cell module package 101 in which shadows and shades 503 are generated is not reduced or generated, but the solar cell module package in which shadows and shadows 503 are not generated except for the solar cell module package 101 is not generated. 503 makes normal development.

Therefore, when the power generation as described above, as shown in Figure 4, due to the difference in the amount of power generation according to the mining conditions, the available voltage and insoluble voltage is generated. Here, the available voltage means that the battery is charged only when the power generation voltage is 12V or more, when the voltage of the battery is 12V. This is called the available voltage. The available voltage is charged to the storage battery 302 and used when necessary, but the unused voltage is discarded since it is not charged. That is, the amount of power generation of each solar cell module package 101 from sunrise to sunset is different, but one example thereof will be described, and the solar cell module package 101 may have a higher than the charging voltage required by the storage battery 302 among the plurality of solar cell module packages 101. There is an available voltage solar module package 111 having a high generation voltage and an insoluble voltage solar module package 112 having a low generation voltage. Among them, the available voltage electricity generated from the available voltage solar module package 111 having a high generation voltage. Since the energy 113 becomes a power generation voltage of 12V or more, which is a storage voltage, the energy 113 is transmitted to the storage battery 302 through the controller 301 so that the battery can be charged immediately. The electrical energy 114 is converted into the available voltage electrical energy 113 through a current collecting process in the harvesting circuit 121 and transmitted to the controller 301.

10: solar power generation unit 20: wind power generation unit 30: control unit 40: frame
101: solar cell module package 102: solar cell module 103: solar cell 104: ribbon line
105: upper solar cell module package 106: lower solar cell module package
111: usable voltage solar cell module package 112: insoluble voltage solar module package
113: available voltage electrical energy 114: insoluble voltage electrical energy
121: harvesting circuit
131: junction box 132: wire inlet 133: power line 134: hinge
201: Generator 202: Shaft 203: Rotating Plate 204: Blade
205: guide 206: guide hole 207: spacing
301: controller 302: storage battery 303: temperature control means
401: upper base 402: lower base 403: support
501: solar flat battery module 502: horizontal axis wind power generator 503: shadow and shadow
504 sun 505 clouds
601: upper stage 602: lower stage 603: support

Claims (6)

The lower base 402 located at the bottom to be coupled to the wind power generation unit, a plurality of supports 403 coupled to the end of the lower base 402, and the upper base 401 coupled to the upper portion of the support 403 A frame 40 including;
A photovoltaic power generation unit 10 coupled to an upper portion of the upper portion of the frame 40 and having a plurality of solar cell module packages 101 formed in multiple directions;
A harvesting circuit 121 for collecting electrical energy generated by the photovoltaic unit 10;
A generator 201 coupled to the lower base 402 of the frame 40, a shaft 202 extending from a vertical axis of rotation of the generator 201, and a plurality of rotating plates horizontally coupled to the shaft 202. 203, a plurality of blades 204 formed and coupled between the rotating plate 203, a plurality of spacings 207 coupled between the rotating plate 203, and the rotating plate 203. A wind power generation unit 20 comprising a plurality of guide holes 206 formed therein, and guides 205 inserted into the guide holes 206 and the spacing 207; And
Multi-directional power generation multi-spherical solar cell module and noise-free low-speed Savoni characterized in that it comprises a control unit 30 for charging and controlling the electrical energy generated in the photovoltaic unit 10 and the wind power generator 20 Hybrid urban hybrid power generation system using Uussian wind power generator delete delete delete delete delete

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