WO2018228204A1

WO2018228204A1 - Road surface power generation unit and system

Info

Publication number: WO2018228204A1
Application number: PCT/CN2018/089167
Authority: WO
Inventors: 王运方
Original assignee: 北京铂阳顶荣光伏科技有限公司
Priority date: 2017-06-12
Filing date: 2018-05-31
Publication date: 2018-12-20
Also published as: JP2019036711A; CN206807124U; KR20180003579U; AU2018204182A1

Abstract

Disclosed are a road surface power generation unit and system. The road surface power generation unit comprises: lower glass disposed on a basic road block of the road surface; a solar cell chip disposed on the lower glass; and upper glass covering the solar cell chip, the lower glass and the upper glass being fixed to the solar cell chip by means of adhesion. According to the road surface power generation unit and system provided by the utility model, the lower glass is disposed on the basic road block, and the solar cell chip is disposed between the upper glass and the lower glass, so that high-efficiency power generation is implemented, easy installation and weather resistance and waterproofing are also implemented, and the tolerance of the road surface is improved.

Description

Pavement power generation unit and system

The present application claims the priority of the domestic filing of the Chinese Patent Office, the application number No. 201720677907.0, entitled "Pavement Power Generation Unit and System" on June 12, 2017, the entire contents of which is incorporated herein by reference.

Technical field

The utility model relates to a solar power generation technology, in particular to a road surface power generation unit and system.

Background technique

With the continuous development of new energy technologies, distributed solar energy provides people with a more convenient energy supply. Distributed solar power requires a certain plane or facade space as a site carrier.

At present, a large number of supporting electrical facilities such as lighting, monitoring, and indications are used in the transportation field, and the demand for electricity is obvious. The task of erecting new or modified roads is becoming more and more arduous; common light pole bracket type, ground bracket type solar energy The way the product is installed is neither aesthetically pleasing nor takes up too much space. Solar applications in the transportation sector In addition to the roof area of the service facilities, there are many spatial locations where solar power generation can be applied. Among them, non-motorized roads account for a large proportion, such as parks, pedestrian streets, etc., the road surface can be used for solar energy, and solar cell chips are laid on it, making it an integrated carrier for landscape facilities, lighting, monitoring, information warning and other functions.

However, since the road surface on which the solar cell chip is laid is often stepped on and bumped, the road surface tolerance is poor, and after long-term use, the light absorption rate of the solar cell chip is affected.

Utility model content

The object of the present invention is to provide a road surface power generating unit and system. The solar cell chip is disposed between the upper layer glass and the lower layer glass by providing a lower layer glass on the basic road block to solve the problems in the prior art, and is efficient. Improve the road surface tolerance while generating electricity.

The basic road block may be a basic road block used on a motor vehicle lane or a non-motor vehicle lane; the basic road block may specifically be a reinforced concrete bottom plate, and the reinforced concrete bottom plate is sequentially provided with a cement mortar screed layer, a base layer Treatment agent, and waterproof coating.

The utility model provides a road surface power generation unit, which comprises:

Lower glass for setting on the basic road block of the road surface;

a solar cell chip fixedly disposed on the lower glass;

The upper glass is covered on the solar cell chip; the lower glass and the upper glass are both fixed to the solar cell chip by adhesive bonding.

The road surface power generating unit as described above, wherein it is preferable that the power generating material of the solar cell chip is a flexible material.

In the road surface power generating unit as described above, preferably, the lower layer glass is an organic glass.

In the road surface power generating unit as described above, preferably, the upper layer glass is tempered glass or plexiglass.

The road surface power generating unit as described above, wherein preferably, each of the road surface power generating units includes one solar cell chip.

The road surface power generating unit as described above, wherein, preferably, the road surface power generating unit further includes a cable and a junction box;

Wherein the cable is electrically connected to the solar cell chip through the junction box;

The cable and the junction box are disposed between the solar cell chip and the lower glass, and the cable and the junction box are embedded in the lower glass.

The road surface power generating unit as described above, wherein preferably, each of the road surface power generating units includes a plurality of solar battery chips.

a road surface power generating unit as described above, wherein, preferably, the road surface power generating unit further includes a cable, a junction box, and a connector;

Wherein, each of the solar cell chips is correspondingly provided with a junction box;

One end of the cable is connected to the junction box, and the other end is connected to the connector;

The connector electrically connects cables connected to different junction boxes to realize series and/or parallel connection of a plurality of solar cell chips; and extracts positive and negative terminals of both ends of the solar cell strings after series and/or parallel connection ;

The cable and the junction box are disposed between the solar cell chip and the lower layer glass, and the cable and the junction box are both embedded in the lower layer glass;

The connectors disposed between adjacent junction boxes are led out from the bottom surface of the lower glass, and the connectors located at both ends of the solar battery string protrude from the side below the lower glass.

The road surface power generating unit as described above, wherein it is preferable that the connector located under the lower glass is sealed by a sealed box.

The road surface power generating unit as described above, wherein, preferably, further comprises an edge banding strip which connects the upper layer glass and the lower layer glass and seals the periphery of the solar cell chip.

The utility model also provides a road surface power generation system, comprising the road surface power generation unit provided by the utility model, the road surface power generation system further comprising a charging controller and a storage battery, wherein the road surface power generation unit generates electricity through the charging control The device outputs to the battery to supply power to the powered device.

The utility model further provides a road surface power generation system, which comprises two or more road surface power generation units provided by the utility model, the road surface power generation system further comprises a convergence device and an inverter, wherein the road surface power generation unit is connected in series After that, power generation is performed, and current is collected by the current collecting device and output to the inverter, and is inverted by the inverter and output to the power grid.

The road surface power generation unit provided by the utility model is provided with a lower layer glass on the basic road block, and the solar battery chip is disposed between the upper layer glass and the lower layer glass, and is easy to install, weatherproof and waterproof, and improves the road surface while achieving high efficiency power generation. Tolerance.

DRAWINGS

1 is a top plan view showing a structure of a road surface power generating unit according to an embodiment of the present invention;

2 is a cross-sectional view of a road surface power generating unit according to an embodiment of the present invention;

Figure 3 is an enlarged view of A in Figure 2;

4 is a schematic diagram of a road surface power generation system according to a preferred embodiment of the present invention;

FIG. 5 is a schematic diagram of a road surface power generation system according to another preferred embodiment of the present invention.

Description of the reference signs:

100-Pavement Power Generation Unit 110-Lower Glass 120-Solar Battery Chip 121-Sealed Box 122-Cable 123- Junction Box 124-Connector 130-Upper Glass 140-Glue 150-Edge Sealing Strip 200-Charging Controller 300- Battery 400 - Electrical equipment 500 - Energy storage battery 600 - Confluence device 700 - Inverter 800 - Power grid

detailed description

The embodiments of the present invention are described in detail below, and the examples of the embodiments are illustrated in the drawings, wherein the same or similar reference numerals are used to refer to the same or similar elements or elements having the same or similar functions. The embodiments described below with reference to the accompanying drawings are intended to be illustrative of the invention and are not to be construed as limiting.

1 is a top plan view of a road surface power generating unit according to an embodiment of the present invention. The embodiment of the present invention provides a road surface power generating unit 100 including a lower layer glass, a solar cell chip 120, and an upper layer glass 130.

The road surface power generating unit 100 can be used for a newly built road surface, and the above lower layer glass is used for setting on a basic road block of a road. The solar cell chip 120 is fixedly disposed on the lower glass, the upper glass 130 is covered on the solar cell chip 120, and the lower glass and the upper glass 130 are fixed to the solar cell chip 120 by adhesive bonding. The power generation material of the solar cell chip 120 may be a crystalline silicon material typified by single crystal or polycrystal, or a flexible material typified by copper indium gallium selenide (CIGS), which has a certain bendability and is strong. The characteristics of the anti-stress deformation.

2 is a cross-sectional view of a road surface power generating unit according to an embodiment of the present invention, and FIG. 3 is an enlarged view of a portion A in FIG. The solar cell chip 120 may be bonded to the underlying glass 110 by a glue 140, preferably by UV shadowless glue or resin glue. The upper glass 130 and the solar cell chip 120 may also be fixed by adhesive bonding, preferably by UV shadowless bonding. The lower glass 110 may be organic glass (PMMA), and the upper glass 130 may be tempered glass or plexiglass (PMMA).

The road surface power generation unit provided by the embodiment of the present invention sets the solar cell chip between the upper layer glass and the lower layer glass by providing the lower layer glass on the basic road block, and is easy to install, weatherproof and waterproof, and improves the high-efficiency power generation. Road tolerance.

The solar cell chip 120 can adopt a CIGS battery chip, has high photoelectric conversion efficiency, and has good weak photoelectric power generation characteristics, so that power can be generated under all weather conditions. Moreover, the CIGS battery chip has good stress resistance and flexibility, and the solar cell chip will not be damaged under complicated conditions such as conducted vibration and temporary deformation of the road surface. CIGS battery chips can be packaged and mounted using soft, corrosion-resistant surface materials. Specifically, ETFE (ethylene-tetrafluoroethylene copolymer) can be used for component packaging. The use of ultraviolet high-intensity UV shadowless glue and PMMA glass layer for pavement installation, resistant to flying sand and stone without crushing, salt and alkali, adapt to road snow melting agent corrosion environment. The solar cell chip can also use a bypass diode to shield the non-power generation area when the light-receiving surface is blocked or damaged, and to ensure continuous power generation in the normal light-receiving area, which is suitable for application in a road scene with complicated occlusion conditions.

In the embodiment of the present invention, the lower glass layer is disposed on the basic road block of the road. In the embodiment of the present invention, the method for setting the lower glass layer on the basic road block of the road is not limited. Alternatively, the lower glass layer 110 may be directly Bonded to the surface of the road, and more optionally, bonded to the surface of the road by glue or cement through the lower glass layer. Since the lower glass layer 110 is directly bonded to the surface of the road, construction is facilitated.

The road surface power generating unit in this embodiment further includes a cable and a junction box connected to the solar cell chip, wherein the cable is electrically connected to the solar chip through the junction box; the junction box is used to connect a solar energy The current of the battery chip is collected and derived. A junction box is disposed on each of the solar cell chips, and the junction box includes a positive output terminal and a negative output terminal for connecting an external device to supply power to the external device.

It should be noted that, when the number of solar battery chips is plural and needs to be connected in series or in parallel, the road surface power generating unit may further include a connector for connecting to the junction box of the solar cell chip through a cable. And electrically connecting the junction boxes of the solar cell chips to realize series and/or parallel connection of the plurality of solar cell chips. That is, one end of the cable is connected to the junction box on the solar cell chip, and the other end is connected to the connector. The connector electrically connects the cables connected to the different junction boxes, realizes series and/or parallel connection of the plurality of solar cell chips, and extracts the positive and negative terminals of both ends of the solar cell strings after series and/or parallel connection. For example, when a plurality of solar cell chips are connected in series, in the adjacent two solar cell chips, a connector is provided, which passes the positive electrode on one of the solar cell chip junction boxes and the negative electrode on the junction box of the other solar cell chip The cables are electrically connected to realize the series connection of two solar cell chips, and so on, and a plurality of solar cell chips are connected in series, and finally, the solar cell chip strings of one end are respectively arranged at the two ends of the solar cell chip strings after the series connection. The positive electrode is taken out, and the negative electrode of the solar cell chip string at the other end is taken out. The case where a plurality of solar cell chips are connected in parallel, or after being connected in series and then in parallel, and in parallel and then in series is similar to the case of series connection, which will not be described in detail in this embodiment. The connectors each include a connector between the junction boxes of two adjacent solar cell chips, and a connector for taking out the positive and negative terminals of the both ends of the solar cell chip in series and in parallel.

Preferably, referring to FIG. 2 and FIG. 3, the road surface power generating unit in this embodiment further includes a cable 122 connected to the solar cell chip 120, and a junction box 123 and a connector 124 connected to the cable 122. Figure 2 and Figure 3. The cable 122 and the junction box 123 are disposed between the solar cell chip 120 and the lower glass 110, and the cable 122 and the junction box 123 are both embedded in the lower glass 110. The connector 124 is disposed between the adjacent two junction boxes 123, and electrically connects the adjacent two junction boxes 123, connects the connectors 124 of the two junction boxes 123 and is led out from the bottom surface of the lower glass 110. A connector 124 at both ends of the solar cell chip string protrudes from the side below the lower glass 110. Preferably, the connector 124 located below the lower glass 110 is sealed by the sealed box 121. The solar cell chip 120 adopts a wiring pattern of the back-out line, uses an anti-aging cable, adopts a modular road surface, and internal wiring, thereby improving the use environment of the cable and improving the life of the cable.

Preferably, the road surface power generating unit provided by the embodiment of the present invention is further provided with an edge sealing strip 150. Referring to FIG. 1 to FIG. 3, the edge sealing strip 150 connects the upper layer glass 130 and the lower layer glass 110, and the solar cell is connected. The periphery of the chip 120 is sealed.

4 is a schematic diagram of a road surface power generation system according to a preferred embodiment of the present invention. The embodiment of the present invention further provides a road surface power generation system, including the road surface power generation unit 100 provided by any embodiment of the present invention. The power generation system further includes a charge controller 200 and a battery 300. The road surface power generation unit 100 generates electricity to output current to the battery 300 through the charge controller 200 to supply power to the power device 400.

In this embodiment, the number of solar cell chips included in the road surface power generating unit is not limited, and may be set according to actual conditions. For example, when the road surface power generating unit is powered by a separate and separated power light with a small power consumption. Only one solar cell chip can be set; when it is necessary to supply power for the signage, charging pile or communication monitoring setting, since the above-mentioned electric equipment requires more electric power, optionally, each road surface generating unit can include more Solar battery chips. In the application scenario of the larger power demand, in this embodiment, multiple road surface power generation units can be connected in series and parallel to realize multi-scene application.

Optionally, each of the road surface power generating units 100 may include 1 to 10 solar battery chips 120. In this embodiment, each of the road surface power generating units 100 includes four solar battery chips 120, and the powering equipment 400 may include a landscape light and an indication. Cards, charging piles and communication monitoring facilities.

The above-described road surface power generation system may further include an energy storage battery 500 for storing electrical energy. The energy storage battery 500 can use a lithium battery to collect surplus solar power under the condition of sunshine, and provide additional energy protection when the solar power is insufficient. The lithium battery has good adaptability to high and low temperature environments.

FIG. 5 is a schematic diagram of a road surface power generation system according to another preferred embodiment of the present invention. The embodiment of the present invention further provides a road surface power generation system, which includes two or more embodiments provided by any embodiment of the present invention. The road surface power generation unit 100 further includes a current collecting device 600 and an inverter 700. The road surface power generating unit 100 is connected in series to generate power, and the current is collected by the current collecting device 600 and output to the inverter 700, and after being inverted by the inverter 700. It is output to the power grid 800, which can supply power to the road surface and roadside equipment. It can also supply power generation facilities for nearby power facilities and buildings, and solve the demand for nearby power equipment.

Preferably, the adjacent two road surface power generating units 100 are sealed by glue, and the above-mentioned connectors 124 at both ends of the road surface power generating unit are sealed in the glue, thereby avoiding the bumpering of the connector 124 and environmental corrosion, thereby improving the wiring. The service life of the device 124.

The structure, features and effects of the present invention are described in detail above based on the embodiments shown in the drawings. The above description is only a preferred embodiment of the present invention, but the present invention does not limit the implementation scope as shown in the drawings. Any changes that are made in accordance with the teachings of the present invention, or equivalents to equivalent changes, are not within the scope of the present invention.

Claims

A road power generating unit, comprising:

Lower glass for setting on the basic road block of the road surface;

a solar cell chip fixedly disposed on the lower glass;

The upper glass is covered on the solar cell chip; the lower glass and the upper glass are both fixed to the solar cell chip by adhesive bonding.
The road surface power generating unit according to claim 1, wherein the power generating material of the solar cell chip is a flexible material.
The road surface power generating unit according to claim 2, wherein the lower glass is made of organic glass.
The road surface power generating unit according to claim 3, wherein the upper layer glass is tempered glass or plexiglass.
The road surface power generating unit according to claim 1, wherein each of said road surface power generating units comprises a solar cell chip.
The road surface power generating unit according to claim 5, wherein the road surface power generating unit further comprises a cable and a junction box;

Wherein the cable is electrically connected to the solar cell chip through the junction box;

The cable and the junction box are disposed between the solar cell chip and the lower glass, and the cable and the junction box are embedded in the lower glass.
The road surface power generating unit according to claim 1, wherein each of said road surface power generating units includes a plurality of solar battery chips.
The road surface power generating unit according to claim 7, wherein the road surface power generating unit further comprises a cable, a junction box, and a connector;

Wherein, each of the solar cell chips is correspondingly provided with a junction box;

One end of the cable is connected to the junction box, and the other end is connected to the connector;

The connector electrically connects cables connected to different junction boxes to realize series and/or parallel connection of a plurality of solar cell chips; and extracts positive and negative terminals of both ends of the solar cell strings after series and/or parallel connection ;

The cable and the junction box are disposed between the solar cell chip and the lower layer glass, and the cable and the junction box are both embedded in the lower layer glass;

The connectors disposed between adjacent junction boxes are led out from the bottom surface of the lower glass, and the connectors located at both ends of the solar battery string protrude from the side below the lower glass.
The road surface power generating unit according to claim 8, wherein the connector located under the lower glass is sealed by a sealed box.
The road surface power generating unit according to claim 9, further comprising an edge sealing strip that connects the upper glass and the lower glass and seals the periphery of the solar cell chip.
A road surface power generation system, comprising the road surface power generation unit according to any one of claims 1 to 10, further comprising a charge controller and a battery, wherein the road surface power generation unit generates electricity by passing current The charge controller outputs to the battery to supply power to the powered device.
A road surface power generation system, comprising: two or more road surface power generation units according to any one of claims 1 to 10, the road surface power generation system further comprising a flow collecting device and an inverter, the road surface After the power generating units are connected in series, power is generated, and the current is collected by the current collecting device and output to the inverter, and is inverted by the inverter and output to the power grid.