阅读说明：本技术 具有地下光室的太阳能发电厂设计 (Solar power plant design with underground light chamber ) 是由 坎·巴朗·尤纳尔 于 2017-12-26 设计创作，主要内容包括：一种新的太阳能发电厂设计,其包括建造在地下的“光室”、用于CSP和CPV发电厂的市售反射镜,以及市售光伏组件。在地下建造的光室通过提高直射光伏模块的阳光的百分比,显著提高太阳光到电的转换效率,其中,所述光伏模块通过风扇保持冷却和清洁。该设计的建设、运营和维护更加容易、快捷和经济。并且显著降低了总体用地需求、单位装机功率投资成本和平准化度电成本(LCOE)。该设计允许在农村和城市地区安装,使得在当前技术水平下不可行的应用成为可能。(A new solar power plant design includes "light rooms" built underground, commercially available mirrors for CSP and CPV power plants, and commercially available photovoltaic modules. Light rooms built underground significantly increase the solar-to-electricity conversion efficiency by increasing the percentage of sunlight that strikes the photovoltaic modules, which are kept cool and clean by fans. The design is easier, faster and more economical to construct, operate and maintain. And the overall land requirement, unit installed power investment cost and standardized electricity consumption cost (LCOE) are significantly reduced. This design allows installation in rural and urban areas, making possible applications that are not feasible under the current state of the art.)

1. A solar power plant design, characterized in that photovoltaic modules for power generation are placed underground.

2. The industrial, residential and commercial use of claim 1, characterized in that said design can be implemented in rural areas with grid-tie connections; implemented in residential or commercial buildings with grid-tied or off-grid connections; in hospitals, universities, entertainment areas such as parks, or similar facilities.

3. A light room, wherein said light room is constructed underground, having a wall covered by any number of photovoltaic modules; the two-sided sidewall, floor and ceiling covered by the reflector and the projection for capturing sunlight make external factors far away from the photovoltaic module and reduce the temperature of the photovoltaic module, thereby improving the power generation efficiency.

4. The cooling system of claim 3, wherein a positive pressure differential is created inside the optical chamber to keep dust, dirt, and external elements away from the photovoltaic module while cooling a surface of the photovoltaic module.

5. A quick installation system of photovoltaic modules is characterized by a quick installation in front of one wall of a light room and easy maintenance, repair or replacement.

6. An inspection room constructed behind the optical cell of claim 3, for performing the activities of claim 5.

7. A gate for providing underground access to sunlight, characterized by the provision of adjustable rotating shutters which provide optimal operation and shut down function in the event of severe events such as thunderstorms, storms, heavy rain or snow, to protect critical equipment.

Technical Field

The present invention relates to a new solar power plant design comprising "light rooms" built underground, commercially available mirrors for Concentrated Solar Power (CSP) and Concentrated Photovoltaic (CPV) power plants, and commercially available Photovoltaic (PV) modules. In contrast to conventional photovoltaic power plants and concentrated solar power plants, photovoltaic modules are placed in underground light rooms. Sunlight is directed and confined in the light chamber by using various mirror arrays. This design increases the power generation by redirecting light reflected by the photovoltaic module onto the photovoltaic module and keeps the surface of the photovoltaic module clean while keeping its temperature below the operating value of conventional solar power plant designs, thereby increasing the power generation per unit area. By keeping dust, dirt, and external factors away from the photovoltaic module, the necessity for periodic cleaning is eliminated, reducing maintenance and operating costs. This design will overhaul the case and build behind photovoltaic module's wall, easily overhaul and insert photovoltaic module and wiring. By using a pre-assembled frame or cassette that can carry the photovoltaic module to be placed, an easier, economical and faster installation can be achieved. By moving the photovoltaic frame and modules into the ground, the environmental footprint is reduced by leaving only three sets of mirror arrays and one shutter with adjustable rotating shutters for sunlight to pass through on the ground. By building underground light rooms, a large portion of the land area in a conventional solar power plant design is reduced, which can be used for agricultural or other conventional purposes.

Background

This section is illustrative of background information related to the present disclosure.

Mirrors are commonly used in CSP and CPV solar power plants in many different configurations. All differently designed solar installations comprise above-ground building elements. The power can be generated by directly concentrating sunlight on the photovoltaic module, or by transferring heat to boiling water through a pipe with molten salt or other high-heat-capacity liquid, so that the power can be generated by a steam turbine generator unit.

The Shockley-Queisser limit or detailed equilibrium limit refers to the maximum theoretical efficiency of a solar cell made from a single P-N junction. This was first calculated by William Shockley and Hans Queisser.

Reference: william Shockley and Hans j. queisser: "Detailed equilibrium limits for the Efficiency of P-N Junction solar cells", "Journal of Applied Physics", Vol.32, p.510-519(1961) (William Shockley and HansJ. Queisser: "delayed Balance Limit of Efficiency of P-N Junction solar cells", Journal of Applied Physics, Volume 32, pp.510-519(1961))

The main obstacles limiting solar power plants to operate close to the theoretical limit of the scherrer-quinsel can be summarized as follows:

influence of light reflection: the sunlight reflected by the photovoltaic modules reduces the percentage of sunlight absorbed, thereby reducing power generation.

Maximum efficiency of a photovoltaic module requires that incident sunlight is not reflected in the process of reaching the absorbing layer, and that light entering the layer is not subsequently reflected out or transmitted through the cell.

A variety of antireflective technologies have been deployed in photovoltaic modules and the subject is still being actively studied. Antireflection techniques can be broadly divided into two categories: 1) anti-reflective coating (ARC) reduces reflection on the light absorbing layer of the cell; 2) a textured surface has two purposes, respectively to increase light transmission and to trap light in the absorber layer. The most effective strategy is often to use these techniques in combination.

Reference: dan M.J.Doble, John W.Graff, Fraunhofer Center for Sustainable Energy Systems, Mass., and the Frounhu Hoff Center of science and Technology (Dan M.J.Doble, John W.Graff, Fraunhofer Center for Sustainable Energy Systems, Mass instruments of Technology, Cambridge MAUSA)http://www.renewableenergyworld.com/articles/2009/03/minimization-of- reflec ted-light-in-photovoltaic-modules.html

Influence of temperature: the temperature and yield of a photovoltaic module are inversely proportional, and therefore, as the photovoltaic module is more exposed to sunlight and heat, its overall efficiency decreases. The black body radiation (blackbody radiation) of a solar cell at room temperature (300 ° K) cannot be captured by the cell, which accounts for about 7% of the available incident energy. The energy lost in the battery is generally converted into heat, and thus, when the battery is exposed to sunlight, the efficiency of the battery may result in an increase in the temperature of the battery. As the cell temperature increases, the black body radiation also increases until equilibrium is reached. In practice, this equilibrium is reached at temperatures up to 360 ° K, at which time the cell also operates less efficiently than it would at room temperature.

The encapsulation of solar cells into photovoltaic modules also produces the undesirable side effect that the encapsulation alters the heat flow into and out of the photovoltaic module, resulting in the operating temperature of the photovoltaic module being increased. The increase in temperature reduces the voltage of the photovoltaic module, thereby reducing the output power, which can have a significant impact on the efficiency of the photovoltaic module. In addition, the temperature increase increases the stress associated with thermal expansion and the rate of aging increases by about two times for each 10 ℃ increase in temperature, and thus, the temperature increase can also lead to various failures or aging of the photovoltaic module.

Reference:

http://ph.qmul.ac.uk/sites/default/files/u75/Solar％20cells_ environmental％20impact.pdf

the influence of external factors such as dust, dirt, rain, wind, snow, storm, etc.: the effect of climate parameters on the performance of photovoltaic panels was examined by detailed analysis of the relationship of two existing photovoltaic devices to the weather to which they were exposed. The results of the indoor experiments show that even a small amount of fine particles reduces the light transmittance by 11%. Dust was collected from exposed glass units and analyzed for distribution and found to have a particle size of less than 400 microns with a maximum frequency of below 20 microns, but due to frequent rain, the effect of dust on solar energy transmitted through the glass after four weeks of exposure was only 5%. Of the various climate parameters used in the statistical analysis, the effects of high humidity, rain and snow on the efficiency of both photovoltaic devices are most significant, and in some cases may destroy any system output. This study also revealed a geographical problem with birds in this coastal city, whose excrements would form hot spots on the photovoltaic panels and reduce their production.

Reference documents: effect of southeast british climate conditions on photovoltaic panel efficiency

https://www.researchqate.net/publication/261218699The effect of weather conditions on the efficiency of PV panels in southeast of UK

Impact of land use: the fourth factor has no direct relation to the efficiency of solar power generation, but has a negative effect on the whole because a solar power plant requires a large area of land.

The amount of land use required by conventional PV and CSP solar power plants sometimes has an adverse effect, i.e. using farming for electricity. Rebecca r.hernandez, university of california (now at berkeley division and lorens berkeley national laboratory, university of california), Madison k.hoffacker (now at the riverside division protection biology center, university of california), and coworkers 2015, published studies evaluating the site selection impact of 161 existing, under-construction and planned-construction large terrestrial solar facilities, california.

Studies have found that 30% of all such solar power plants are located in farmlands or pastures, which adversely affect agricultural production and food production capacity. The solution proposed by this research is to reduce the distance between the photovoltaic module and the mirror array.

According to the novel solar power plant design, the photovoltaic module and equipment related to power generation are moved underground, and the primary and secondary reflector arrays, the adjustable rotary baffle plate and the gate are only left on the ground, so that the influence caused by building a solar power plant is greatly reduced.

Reference:https://carnegiescience.edu/news/solar-energy's-land-use-impact

reducing land use requirements is also beneficial in reducing the impact on wildlife.

Disclosure of Invention

This section merely summarizes the disclosure generally and does not disclose its full scope or all of its features.

The present invention provides a solar power plant design approach that is different from current CSP and PV designs by combining existing reflection-based solar power generation technologies with commercially available photovoltaic modules. The two main concave mirror arrays are arranged in a straight line and are arranged opposite to each other for concentrating and focusing sunlight to the internal reflection surface of the secondary mirror array, and the secondary mirror array is placed on the ground at a high level and is parallel to the gate. The focused sunlight is reflected at an angle that directs the light to the focal point of the secondary mirror array. The sunlight thus reflected passes through a shutter, which is an open channel dug in the ground and extending along a line intersecting the projection of the secondary mirror array. The gate is provided with a pair of adjustable rotating shutters, the inner sides of which facing each other are covered with a mirror. Sunlight enters a light room built underground through a gate; thus, sunlight is directed to the "photovoltaic module wall" to generate electricity. Light that is not absorbed by the photovoltaic module and reflected by it is trapped in the light chamber by means of mirrors mounted on the walls, floor and ceiling on both sides of the light chamber, the inside surface of the adjustable rotating blind, the protrusions running parallel to the walls of the photovoltaic module and hanging on both sides of the ceiling of the light chamber. In this way, light reflected by the photovoltaic modules can be reflected back onto the modules almost indefinitely, greatly increasing the conversion efficiency of the photovoltaic modules and allowing more power to be generated per device.

An optical cell is a room built underground, which includes:

a gate dug out along a line parallel to the projection of the secondary mirror array; the gate is provided with a pair of adjustable rotating baffles, the inner side surfaces of the adjustable rotating baffles are covered with reflectors, and the angles of the adjustable rotating baffles can be changed to enable sunlight to irradiate the light chamber to the maximum extent;

a wall completely covered on one side by a commercially available photovoltaic module for generating electricity;

two side walls, a floor and a ceiling covered with mirrors for capturing the sunlight reflected by the photovoltaic module indoors and returning it to the photovoltaic module;

a protrusion running parallel to the gate, which is disposed on the ceiling and is also covered with the reflecting mirror at both sides thereof;

heating, ventilation and air conditioning (HVAC) systems for cooling and pressurization consisting of a wall covered with a fan for creating a positive pressure differential within a light chamber to prevent the ingress of dust, dirt and other external elements; and simultaneously cooling the photovoltaic module to improve the power generation capacity. The hvac system for cooling and pressurizing may be of conventional design and use commercially available components. However, any other way of designing it to not have to cover the entire side wall can be used, so that more mirrors are used to direct more sunlight to the photovoltaic modules, increasing the power production.

The service room is configured behind the photovoltaic module wall to facilitate maintenance, overhaul, periodic inspection or replacement of the photovoltaic module, the service room also houses cables from the photovoltaic module to the combiner box.

The power generated in this manner is then transmitted from the combiner box to the step-up transformer and finally to the grid in any of the conventional power transmission system designs. Other use cases may include urban or rural, grid-connected or off-grid, commercial and residential buildings, recreational areas, hospitals, universities, and the like.

Drawings

The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.

Fig. 1 shows the general arrangement of the solar power plant design of the present invention. As shown by the solid and dashed black lines, it can be seen that the different paths of the male light beam are reflected by different mirror surfaces before reaching the light chamber. The system comprises two main commercial concave mirror arrays arranged on the ground in an opposite mode, two secondary concave mirror arrays which are higher than the main arrays and are arranged in a downward mode, a pair of adjustable rotary baffles, a gate and a light chamber; and also includes a wall that is completely covered by the photovoltaic module, two-sided walls that are completely covered by the reflector, a floor and ceiling, and a wall that houses a fan that generates a positive pressure differential to keep external factors such as dust and dirt away from and cool the photovoltaic module.

Fig. 2 illustrates the working principle of power generation, wherein sunlight is reflected back and forth in the light room, effectively capturing as much sunlight as possible. Many of the sunlight that reaches the primary mirror array at different angles can be traced until they directly reach the wall covered by the photovoltaic module; or, as shown by the return line, to the photovoltaic module after reflection by any surface covered by a mirror, the inside and outside surfaces of an adjustable rotary shutter, or a protrusion. The back of the wall covered by the photovoltaic module is provided with an overhaul room which can facilitate the installation, maintenance and operation of the photovoltaic module; wiring from the photovoltaic modules to the combiner box is also facilitated.

Fig. 3 shows a perspective view of fig. 2, and also together illustrate the manner in which the electricity produced thereby is transmitted from the photovoltaic module to two different example terminals. The illustrated example of access to the grid includes paths from the string inverter, combiner box, step-up transformer, and grid, respectively. The example of a commercial building shows the connection from the combiner box to the building.

Fig. 4 shows a perspective cross-sectional view of the light chamber looking toward the wall of the photovoltaic module. The front wall is completely covered by the photovoltaic module, the left wall comprises a fan for cooling the photovoltaic module, generating a positive pressure differential, keeping the light room free from external factors; the other two walls and ceiling are covered with reflectors to reflect and capture the internal sunlight.

Detailed Description

Example embodiments will now be described more fully with reference to the accompanying drawings.

Fig. 1 shows two sets of primary mirror arrays 5 of commercially available concave mirrors placed opposite each other on the ground. The primary mirror array 5 runs parallel to the gate 8 and has an adjusted curvature and focus so that sunlight can be reflected to the secondary mirror array 6, the secondary mirror array 6 reflecting sunlight causing it to pass through the adjustable rotating shutter 7, gate 8 and into the light chamber 9 in sequence. The inner side surface of the adjustable rotating shutter 7 is also covered with a mirror to increase the amount of light reflected to the light chamber 9. The number, type, focus and type and length of the mirrors provided, the number, type and length of the primary mirror array 5, secondary mirror array 6, adjustable rotating blind 7 and gate 8 may be selected according to the design criteria and planned power generation of the solar power plant. The arrangement of the primary 5, secondary 6, adjustable rotating 7 and gate 8 on the ground and the orientation of each other is for exemplary purposes only and may be varied according to the design criteria and optimum power output of the solar power plant. The side walls of the light chamber 9 are covered with photovoltaic modules 11 and the floor of the light chamber 9 may be partially covered with mirrors 10. The floor length of the light room 9 extends below ground as shown by the dashed lines towards the other side with the fan. The light chamber 9 is a rectangular underground space, but other three-dimensional shapes can be built to optimize the construction process and the output power of the solar power plant design.

Fig. 2 shows the propagation of sunlight, which passes directly through or is reflected by the adjustable rotating baffle 7, from the primary mirror array 5 to the secondary mirror array 6, through the gate 8, into the light chamber 9, and is then re-reflected at different angles by different surfaces such as the floor, ceiling, two side walls and two sides of the protrusion 12, which are covered with the mirrors 10; and finally to the photovoltaic module 11 placed on the other side wall. The solid line represents the sunlight directly reaching the photovoltaic module 11, while the return line represents the sunlight that is reflected once by the photovoltaic module and returns to the photovoltaic module after being reflected several times by the surface covered by the mirror. The light chamber 9 actually promotes nearly infinite reflection, thereby effectively trapping sunlight indoors and providing more sunlight to the photovoltaic module 11 than conventional designs. The primary 5 and secondary 6 mirror arrays may or may not be provided with tracking mechanisms 13 and the adjustable rotating shutter 7 may be positioned in a radially open or closed manner to capture the maximum amount of sunlight during the day in the light chamber 9. For maintenance, replacement of the photovoltaic modules 11, for other operational reasons or in the case of emergencies such as rainstorms, snowfalls, storms, earthquakes, floods, the adjustable flap 7 can be closed to shut down the power plant and protect sensitive equipment. The mirror 10 may be flat or any other geometric shape; the design can be arranged in line or in any other direction for maximum power production. In the design example shown in fig. 2, only the corner sides of the floor are covered with obliquely placed flat mirrors. The service room 14 houses cables 16 that pass from behind the photovoltaic modules 11 through the string inverters 15 to the combiner box 17; all devices are of the commercially available type and are installed in a conventional layout design. The power transmission equipment layout shown includes a commercially available string inverter 15 between the photovoltaic module 11 and the combiner box 17, however, this configuration is for exemplary purposes only and is not intended to limit the design scope; any one of the conventionally used solar power plant designs may be optionally installed. The service room 14 can be designed as a flat space with stairs, a room with suitable cable access or a control room with staff space for online energy production monitoring. The primary function of the service room 14 is to facilitate access to the photovoltaic modules 11 for installation, maintenance or replacement.

Fig. 3 is a perspective view of the solar power plant design described so far, showing the final path along which the generated electricity is transported. For ease of understanding, two examples suitable for industry and commerce are shown on the same drawing; one is the application in rural areas with grid connection, where the produced power is transferred from the photovoltaic modules 11 to the combiner box 17, the step-up transformer 19 and the grid connection 20, respectively. Another example is a commercial or residential building 21, which is of the off-grid type using different solar devices, which is not described in detail. Both examples are for illustrative purposes only and are not intended to limit the scope of the designs or devices used.

Fig. 4 shows a cross-sectional view of the light chamber 9 showing the side walls covered by the photovoltaic module 11. The type, number, row number, and number of photovoltaic modules 11 per row may be selected based on the design criteria and power output requirements of the solar power plant. As shown, the ceiling, floor and right side walls of the light room 9 are covered by mirrors 10, the type and orientation of which may also be selected according to design criteria. As shown, a fan 18 is mounted on the left side wall, the fan 18 being used to create a positive pressure differential within the light chamber 9, thereby preventing dust, dirt and other external factors that negatively affect the power output of the power plant or cause operational risks; the fan 18 also cools the photovoltaic module 11 to improve the power generation efficiency. The air inlet of the fan may be placed at any convenient location. A suitable filtering device, which may be a high efficiency air filter (HEPA), should be used to avoid reducing the conversion efficiency of the photovoltaic modules 11. The above-described design layout is for exemplary purposes only and is not intended to limit the scope of the pressurization and cooling functions of the system. Providing a fan on one side wall of the light chamber 9 reduces the reflected light reaching the photovoltaic modules 11 and reduces the power production. Therefore, it is also possible to use another design, i.e. to use less wall space in the light room 9, or to use a heating, ventilating and air conditioning system (HVAC system) placed completely outside the light room 9, which can be placed behind the walls covered with photovoltaic modules 11, to achieve the effect of a positive pressure difference as well and to cool the photovoltaic modules sufficiently.

Industrial applicability

The present invention discloses a new solar power plant design with a different configuration than the prior art.

Solar power plant designs utilize an underground light room to house photovoltaic modules for power generation. This design can solve many of the problems currently faced by the solar industry as described in the background.

First, the underground light chamber significantly increases the amount of sunlight converted to electrical energy by the photovoltaic modules through the use of mirrors.

Second, the cooling system in the light room further increases the power generation by cooling the photovoltaic modules to the required temperature.

Thirdly, the light chamber has an isolation characteristic through the positive pressure difference, so that dust, dirt and external particles can be far away from the photovoltaic module, and the power generation capacity is further improved.

Fourthly, the design of the light chamber is beneficial to more economical and faster construction and installation, the overhaul is more convenient, key equipment cannot be threatened by serious natural events, and the operation and maintenance cost is reduced in the service life of the solar power plant.

Fifth, the photovoltaic modules, cooling system, and service room being installed underground saves valuable land for agricultural or other conventional use.

Sixth, based on the above-mentioned features of saving land, the design is suitable for both grid-connected and off-grid connections for use in rural areas, and for use in commercial or residential buildings. All of these factors, taken together, greatly reduce the leveled cost of electricity (LCOE) of the inventive design, the investment per installed power, and the need for large-scale land use. This opens up new possibilities for investments which cannot be realized with the current state of the art.

The solar power plant design of the present invention can be applied in rural areas, commercial and residential buildings, hospitals, universities, parks, recreational areas or similar facilities.

The claims (modification according to treaty clause 19)

1. A solar power plant design, as shown in fig. 1 to 4, characterized in that the sunlight is directed by means of a curved array of mirrors to an underground "light room (9)", said light room (9) being specifically constructed for housing a wall completely covered by photovoltaic modules on one side; two side walls, floor, ceiling and protrusions (12) covered by the reflector (10); and a one-side wall as a cooling system covered by a fan (18); the design may use commercially available mirror arrays, photovoltaic modules, factory balancing equipment, fans, cooling and grid connection equipment. The solar power plant design increases the sunlight reflected to the photovoltaic modules by using different sets of mirrors (5, 6, 10); -keeping dust and dirt away from the photovoltaic module surface (11) by creating a positive pressure difference within the light chamber (9); and maintaining a low temperature of the photovoltaic module by using a fan (18), thereby improving conversion of sunlight to electricity. The tracking structure (13) may optionally be used. According to the above design, convenient and economical installation can be performed through the quick installation frame for installing the photovoltaic module, and operation and maintenance costs can be reduced because the photovoltaic module is kept away from dust, dirt, rainwater, lightning, snow, rainstorm, sand storm, and the like. The design reduces the valuable land used compared to existing solar power plants for power generation, and the saved land can be used for farming, public facilities or buildings, agricultural or urban areas, or other public or private uses.

2. The industrial, residential and commercial use of claim 1, characterized in that said design can be implemented in rural areas with grid-tie connections; implemented in residential or commercial buildings with grid-tied or off-grid connections; in hospitals, universities, entertainment areas such as parks, or similar facilities.

3. A light room built underground with one wall covered by any number of photovoltaic modules, as shown in figure 4; two side walls, floor and ceiling and protrusions (12) covered by the reflector; a side wall as part of the cooling system covered by a fan (18); and a gate (8) for sunlight to enter; as shown in fig. 2, sunlight which is not absorbed by the photovoltaic module can be reflected multiple times by the light chamber (9) and guided back to the photovoltaic module, thereby increasing the amount of electricity generated; by means of the adjustable rotary flap (7) of the gate (8), power generation can be suspended by closing the gate (8) in the event of rain, lightning, snow, storms, sand storms, etc. A cooling system having a fan (18) disposed on one side wall increases the efficiency of conversion of sunlight to electricity by cooling the photovoltaic module while keeping dust and dirt away from the photovoltaic module by creating a positive pressure differential. The cooling system also reduces operational and maintenance costs by keeping the photovoltaic module surface clean and protecting the photovoltaic module from heavy rain, lightning, snow, rain storms, sand storms, and the like.

4. The cooling system of claim 3, wherein a positive pressure differential is created inside the optical chamber of claim 3 to keep dust, dirt, and external factors away from the photovoltaic module while cooling a surface of the photovoltaic module.

5. A system for rapid installation of photovoltaic modules, characterized by a rapid installation and easy maintenance, repair or replacement in front of a wall of the light chamber of claim 3.

6. An inspection room constructed behind the optical cell of claim 3, for performing the activities of claim 5.