KR101845346B1 - Artificial intelligent shading membrane-based renewable energy grid system, and method thereof - Google Patents

Abstract

The present invention relates to an artificial intelligent awning screen-based renewable energy grid system and a method thereof. Electric energy using sunlight which is renewable energy is collected for each section by using a set of smart grid units consisting of a plurality of artificial intelligent awning screens, a meter reading terminal, and an electric charging station. The collected electric energy is managed by a central server, thereby efficiently supplying the energy to an electric vehicle requiring electric charging. Also, energy supply and demand management can be efficiently performed from a viewpoint of a power supplier by operating as a performance pay for power rate reduction to the power supplier through production of the electric energy for each section. The artificial intelligent awning screen-based renewable energy grid system comprises: the set of the smart grid units; a renewable energy grid server; an LBS server; a power service company server; and a manager terminal.

Description

Technical Field [0001] The present invention relates to an artificial intelligent shading membrane-based renewable energy grid system,

More particularly, the present invention relates to a new and renewable energy grid system based on an artificial intelligent canopy membrane, and more particularly, to a new and renewable energy grid system based on an artificial intelligent canopy membrane, An artificial intelligent shading membrane-based renewable energy grid system and method for collecting electric power energy using solar energy as a renewable energy and managing the collected electric power energy in a central server to efficiently provide electricity to a place where electric charging is required .

Electricity for operating electric appliances such as household appliances used at home or office equipment used in offices is generally supplied through electric power plants operated by KEPCO, transmission lines, and wiring lines in this order to be.

It is a central power source rather than a distributed power source. It has a radial structure that spreads from the center to the periphery, and is characterized by a one-way supplier center rather than a consumer center.

On the other hand, crosswalks are usually installed at intersections of crosswalks and roads so that people can pass through them. Traffic lights are installed on the crosswalks so that people can pass safely in order to prevent safety accidents. Recently, a shading device is installed near a pedestrian crossing so that it can get away from the cold and the heat before crossing the pedestrian crossing.

In addition to this, a large number of awnings panels and awnings are installed in order to avoid sunlight mainly in a small or large athletic field, a camping place, and the like.

Korean Patent Application No. 10-2013-0068103 entitled " Method, Server and System for Providing Heating Energy in Energy Grid "

In order to solve the above problems, the present invention utilizes a collection of Smart Grid units composed of a plurality of artificial intelligent shading films, a meter reading terminal, and an electric charging station to collect electric energy using solar energy, which is new and renewable energy, And to provide a new and renewable energy grid system based on an artificial intelligent sheath membrane and a method for efficiently collecting the collected electric power energy in an electric vehicle requiring electric charge management by a central server.

In addition, the present invention provides an artificial intelligent beveling membrane for efficiently performing energy supply management from the viewpoint of a power supplier by allowing the electric power supplier to operate as a performance fee for reducing electric power charges to electric power suppliers through the production of electric power for each zone Renewable energy grid system and method therefor.

In addition, the artificial intelligent shading films constituting the system of the present invention are self-driven based on sunlight, which is renewable energy, and can perform autonomous shading control based on artificial intelligence and big data And is intended to provide a new renewable energy grid system based on artificial intelligent sheeting membrane and a method thereof, in which temperature control and angle of awakening can be set according to each period using renewable energy.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, an artificial intelligent shading film-based renewable energy grid system according to an embodiment of the present invention includes a plurality of artificial intelligent shingles 100, a meter probe 300, an electric charging station 400, A set of Smart Grid units 1 each having at least one Smart Grid unit 1 composed of each artificial intelligent shading film 100 and a transmission line 2 connected to the electric charging station 400; A renewable energy grid server 600 connected to each smart grid unit 1 by a network 500; The renewable energy grid server 600 further includes a communication unit 610, a smart grid platform 620, and a database 630. The smart grid platform 620 includes a communication unit 610, a smart grid platform 620, The platform 620 receives a plurality of artificial intelligence beans 300 allocated from the "each inspecting terminal 300" of each Smart Grid unit 1 constituting the aggregate of smart grid units 1 to each inspecting terminal 300 So that the surplus electric energy on the rechargeable battery 125 for each zone of the membrane 100 is received in real time via the network 500 by the " power energy information "filled in the electric charging station 400 via the transmission line 2. [ A big data collection module 621 for storing the identification number, location information, zone information, and real-time power energy information of each meter-reading terminal 300 in the database 630; The communication unit 610 is controlled to request the power energy information provided for each rechargeable battery 125 of each of the plurality of artificial intelligent shading films 100 managed by the respective meter reading terminals 300 through the network 500 When the power energy information between the artificial intelligent shading films 100 in the same direction or within a predetermined position range is different by more than a predetermined error range, The control unit 610 controls the communication unit 610 to transmit the real-time power energy information of the target artificial intelligent shine film 100, which has been requested to be inspected, to the manager terminal through the controller 500, A condensing efficiency type lens 112, a condensing space 113, a curved solar cell array 114, a curved solar cell array body 114a, and a first heat insulating panel (not shown) 115) A per-zone power measurement module 622 that allows for an on-board check to be performed; The control unit 610 controls the communication unit 610 to receive an electric charging station information request from the electric vehicle terminal 700 through the network 500 and displays the terminal number, the location information, and the electric power of the electric vehicle terminal 700 that transmitted the electric charging station information request, The control unit 610 controls the communication unit 610 to request and receive the charging request amount through the network 500 to the electric vehicle terminal 700 and then transmits the charging request amount to the meter probe terminal 700 having the zone information closest to the received electric vehicle terminal 700 300 extracted from the database 630 and extracts the inspected power energy information of the electric charging station 400 managed by the inspected terminal 300. When the extracted electric energy information requests the electric charging station information It is analyzed whether it is sufficient to accommodate the electric charge requirement of the electric vehicle terminal 700 and if it is analyzed that it is not sufficient to accommodate the electric charge requirement of the electric vehicle terminal 700, Extracts the identification number of the inspection terminal 300 having the location information of the aircraft terminal 700 and the adjacent area information next and extracts the electric energy information of the electric charging station 400 managed by the inspection terminal 300 And then analyzes the electric charging station 400 information which is analyzed to be sufficient to accommodate the electric charging demand and the information of the electric charging station 400 A power mediation module 623 provided to the terminal 700; And the electric vehicle terminal 700, and controls the communication unit 610 to receive the payment information according to the amount of electric charge, and supplies the electric energy information for each zone to the electric service company server through the network 500 on a cycle-by-cycle basis , And controls the communication unit 610 to transmit a charge reduction request proportional to the accumulated power energy information to the power service company server through the network 500 for the home or industrial complex corresponding to each zone An electrical charge settlement module 624 for each zone to be controlled; The power mediation module 623 may be configured to determine whether the power energy information is sufficient to accommodate the electric charge requirement of the electric vehicle terminal 700 requesting electric charging station information, 700 and the magnitude of the real time power energy information of the electric charging station 400 are compared with each other and when the real time electric energy information is larger than the electric charging charge amount, the electric charging station 400 or the meter reading terminal 300 Real-time electric charging by another electric vehicle terminal is not required on the road between the positional information and the positional information of the electric vehicle terminal (700).

At this time, in the artificial intelligence shining membrane-based renewable energy grid system according to the embodiment of the present invention, the meter probe terminal 300 for each zone measures the charged electric energy information of the electric charging station 400, And then transmits the meter energy information to the renewable energy grid server 600 through the network 500. FIG.

The artificial intelligent bevel membrane-based renewable energy grid system and method thereof according to an embodiment of the present invention can utilize a collection of smart grid units composed of a plurality of artificial intelligent bevel films, a meter probe terminal, and an electric charging station, It collects the electric power energy using the solar energy in each zone and provides the effect that the collected electric power energy can be managed by a central server and efficiently supplied to an electric vehicle requiring electric charging.

In addition, the artificial intelligent shading membrane-based renewable energy grid system and method thereof according to another embodiment of the present invention can operate as a performance repair for reducing electric power charges to electric power suppliers through the production of electric energy for each district, Provides the effect of enabling efficient management of energy supply and demand from the supplier's perspective.

In addition, the artificial intelligent shading film-based renewable energy grid system and method thereof according to another embodiment of the present invention is characterized in that each of the artificial intelligent shading films constituting the system is based on sunlight as a renewable energy It can perform its own driving, it can perform autonomous shading control based on artificial intelligence and big data, and it is possible to adjust the temperature and angle of angle by using new and renewable energy according to each period. to provide.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an artificial intelligent shading film-based renewable energy grid system according to an embodiment of the present invention; FIG.
FIG. 2 is a block diagram illustrating components of a renewable energy grid server 600 among the renewable energy grid systems based on the artificial intelligent canopy membrane according to the embodiment of the present invention shown in FIG.
3 is a view showing a method of providing a renewable energy grid based on an artificial intelligent shading film according to an embodiment of the present invention.
FIGS. 4 and 6 are cross-sectional views illustrating an artificial intelligent beveling film 100 in an artificial intelligent beveling film-based renewable energy grid system according to an embodiment of the present invention.
7 is an exploded cross-sectional view for explaining the components of the artificial intelligent sheath membrane 100 in the artificial intelligent sheath membrane-based renewable energy grid system according to the embodiment of the present invention.
FIG. 8 is a block diagram specifically illustrating the components of the control unit 120 of the artificial intelligent shading film 100 in the artificial intelligent shading film-based renewable energy grid system according to the embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In the present specification, when any one element 'transmits' data or a signal to another element, the element can transmit the data or signal directly to the other element, and the at least one other element Data or signal can be transmitted to another component.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an artificial intelligent shading film-based renewable energy grid system according to an embodiment of the present invention; FIG. Referring to FIG. 1, the artificial intelligent shading membrane-based renewable energy grid system includes a plurality of artificial intelligent shingles 100, a meter probe 300, an electric charging station 400, A smart grid unit body 1 composed of at least one smart grid unit body 1 composed of a transmission line 2 connected to an electric charging station 400 and a plurality of smart grid unit bodies 1 connected to each smart grid unit body 1 via a network 500 Renewable energy grid server 600 "as a basic component, and further, an LBS server, a power service provider server, and an administrator terminal may be further formed.

The network 500 may be a next-generation wired and wireless network for providing Internet or high-speed multimedia service, which is a high-speed period network of a large-sized communication network capable of large-capacity, long-distance voice and data services. When the network 500 is a mobile communication network, it may be a synchronous mobile communication network or an asynchronous mobile communication network. As an embodiment of the asynchronous mobile communication network, a WCDMA (Wideband Code Division Multiple Access) communication network is exemplified. In this case, although not shown in the drawing, the network 500 may include a Radio Network Controller (RNC). Meanwhile, although the WCDMA network is taken as an example, it may be a next generation communication network such as a 3G LTE network, a 4G network, and a 5G network, or an IP network based on other IPs. The network 500 is a system in which signals and data are exchanged between a Smart Grid unit 1 constituting a set of Smart Grid units 1, a renewable energy grid server 600, an LBS server, a power service provider server, It is a role to deliver.

FIG. 2 is a block diagram illustrating components of a renewable energy grid server 600 among the renewable energy grid systems based on the artificial intelligent canopy membrane according to the embodiment of the present invention shown in FIG. 2, the renewable energy grid server 600 includes a communication unit 610, a smart grid platform 620 and a database 630. The smart grid platform 620 includes a big data collection module 621, A per-zone power measurement module 622, a power mediation module 623, and a per-zone electricity billing module 624.

Hereinafter, the artificial intelligent shading film-based renewable energy grid system will be specifically described focusing on the components of the smart grid platform 620.

The big data collection module 621 collects a plurality of artificial intelligence data from the "each inspecting terminal 300" of each Smart Grid unit 1 constituting the set of Smart Grid units 1 Power energy information "obtained by charging the electric charging station 400 via the power transmission line 2 with the spare electric power energy on the rechargeable battery 125 for each zone of the intelligent shade film 100 is received in real time via the network 500 And controls the communication unit 610 to perform the control.

 That is, the meter reading terminal 300 for each zone reads the charged electric energy information of the electric charging station 400 to be managed and transmits it to the renewable energy grid server 600 through the network 500 in real time The big data collection module 621 stores the identification number, the location information, the zone information, and the real-time power energy information of each meter-reading terminal 300 in the database 630.

The per-zone power measurement module 622 requests power energy information provided for each rechargeable battery 125 of each of the plurality of artificial intelligent shading films 100 managed by the metering terminal 300 through the network 500 By controlling the communication unit 610, it is possible to receive the power energy information for each artificial intelligent shading film 100.

Here, the area-specific power measurement module 622 determines whether or not the power energy information between the artificial intelligent shading films 100 in the same direction (road side, residential street, etc.) and similar position range If there is a difference between the error range and the difference, the communication unit 610 is controlled to transmit real-time power energy information of the target artificial intelligent shine film 100, which has been requested to be checked, to the administrator terminal via the network 500 A condensing efficiency type lens 112, a light condensing space 113, a curved solar cell array 114, a curved solar cell array body (not shown) constituting each curved solar cell array module 110, 114a, and the first insulation panel 115, for example, by dust or the like.

The power mediation module 623 controls the communication unit 610 to receive the electric charging station information request from the electric vehicle terminal 700 through the network 500. [

The power mediating module 623 transmits the terminal number, the location information and the electric charge request amount of the electric vehicle terminal 700 that transmitted the electric charging station information request from the electric vehicle terminal 700 of the step S140 through the network 500 And controls the communication unit 610 to store the data in the database 630.

The power mediating module 623 firstly extracts the identification number of the meter reading terminal 300 having the zone information closest to the received position information of the electric vehicle terminal 700 in the database 630, The electric power energy information of the electric charging station 400 managed by the electric power charging station 400 is extracted.

The power mediation module 623 analyzes whether the second extracted power energy information is sufficient to accommodate the electric charging demand of the electric vehicle terminal 700 requesting electric charging station information.

The power mediating module 623 compares the electric charge request amount of the electric vehicle terminal 700 with the magnitude of the real time electric energy information of the electric charging station 400 in a primary comparison Based on the location information of the electric charging station 400 or the meter-reading terminal 300 and the location information of the electric vehicle terminal 700 or the electric vehicle based on the LBS, when the real-time electric power energy information is larger than the electric charge charging amount It can be determined that there is no real-time electric charging request by another electric vehicle terminal within one distance information. Alternatively, as another embodiment of the present invention, the power mediating module 623 may determine that the real-time power energy information of the electric charging station 400 is sufficient when the electric power charging information of the electric charging station 400 is more than a predetermined multiple have.

The power mediating module 623 analyzes the electric power of the meter terminal 300 having the location information of the electric vehicle terminal 700 and the next adjacent area information, Extracts the electric energy information of the electric charging station 400 managed by the extracted meter terminal 300 and extracts the electric energy information of the electric charging station 400 from the electricity terminal 700 Again.

If it is not sufficient to accommodate the electric charging request amount even in relation to the furthest probe terminal 300 through the above process, the power mediating module 623 searches for a delay time for a preset time It is possible to provide the electric vehicle terminal 700 with electric charging station 400 information sufficient to accommodate the electric charging demand in the order of distance.

On the other hand, if the analysis result shows that the electric vehicle terminal 700 is sufficient to accommodate the electric charge requirement, the power mediating module 623 notifies the electric vehicle terminal 700 of the real time location information provided by the LBS server via the network 500 It is possible to control the communication unit 610 to mediate a navigation service for location tracking guidance based on the location information of the metering terminal 300 collected by the big data collection module 621 using the information.

The electric charge settlement module 624 for each zone controls the communication unit 610 to receive electric charge completion information and settlement information corresponding to the electric charge amount from the electric vehicle terminal 700 after completion of charging the electric vehicle, And stores the power energy information provided from the metering terminal 300 divided for each zone.

The electricity bill settlement module 624 for each zone not only provides the communication unit 610 to provide the power energy information for each zone to the power service company server through the network 500 on a cycle-by-cycle basis, And control the communication unit 610 to transmit the electric charge deduction request for the home or industrial complex corresponding to the zone to the electric power service company server through the network 500. [ Here, the power service provider server may be a server managed by a power supplier such as KEPCO.

3 is a view showing a method of providing a renewable energy grid based on an artificial intelligent shading film according to an embodiment of the present invention. Referring to FIG. 3, each artificial intelligent canopy 100 assigned to a group of electric charging stations 400 transmits the spare electric energy on the rechargeable batteries 125 for each area through the transmission line 2 (S110) .

After the step S110, each of the metering terminal 300 reads the charged power energy information of the electric charging station 400 to be managed and transmits it to the renewable energy grid server 600 through the network 500 in real time (S120).

After step S120, the renewable energy grid server 600 stores the identification number, the location information, the zone information, and the real-time power energy information of the respective meter reading terminals 300 in the database 630 (S130).

After step S130, the renewable energy grid server 600 receives an electric charging station information request from the electric vehicle terminal 700 through the network 500 (S140).

After step S140, the renewable energy grid server 600 transmits the terminal number, the position information, and the electric charge request amount of the electric vehicle terminal 700 that transmitted the electric charging station information request in step S140 to the electricity From the vehicle terminal 700 via the network 500, and stores the received data in the database 630 (S150).

After step S150, the renewable energy grid server 600 transmits the identification number of the meter reading terminal 300 having the zone information closest to the location information of the electric vehicle terminal 700 received in step S150 to the database 630 And then extracts the meter energy information of the electric charging station 400 managed by the meter-reading terminal 300 extracted in step S160.

After step S160, the renewable energy grid server 600 receives the electric energy charging information of the electric vehicle terminal 700 requesting electric charging station information in step S150 It is analyzed whether it is sufficient (S170). In one embodiment of the present invention, the electric charge demand of the electric vehicle terminal 700 is firstly compared with the magnitude of the real-time electric energy information of the electric charging station 400, and the real- The electric vehicle terminal 700 or the location information of the electric vehicle based on the location information of the electric charging station 400 or the meter terminal 300 and the location information of the electric vehicle 700 based on the LBS, If there is no real-time electric charge request by the user, it can be judged to be sufficient. Or when the real-time power energy information of the electric charging station 400 is larger than a preset multiple of the electric charging demand amount of the electric vehicle terminal 700. [

After step S170, the renewable energy grid server 600 proceeds to step S190 depending on whether or not it is sufficient to accommodate the electric charging demand of the electric vehicle terminal 700 as a result of the analysis in step S170, ).

In other words, when the analysis result is not sufficient, the renewable energy grid server 600 extracts the identification number of the meter terminal 300 having the location information of the electric vehicle terminal 700 and next adjacent area information, The power energy information of the electric charging station 400 managed by the control unit 300 is extracted (S180a), and then the process proceeds to step S170 again to analyze again whether or not it is sufficient. If this is not enough to accommodate the electric charging demand even with respect to the meter-reading terminal 300 which is farthest from the earliest to the last meter-reading terminal 300, a search is performed again with a delay time for a preset time, It is possible to provide the electric vehicle terminal 700 with electric charging station 400 information sufficient to accommodate the required amount.

After the step S180, the renewable energy grid server 600 transmits the renewed energy grid server 600 to the meter terminal (700) collected in the step S130 using the real-time location information provided by the LBS server via the network 500 The navigation service for location tracking guidance can be mediated by the location information of the mobile terminal 300 (S 190).

After the step S190, the renewable energy grid server 600 receives the electric charge completion information and the payment information according to the electric charge amount from the electric vehicle terminal 700 and transmits the information to the inspection terminal 300, As the power energy information provided in step S200.

After step S200, the renewable energy grid server 600 not only provides the power energy information for each zone to the power service company server through the network 500 on a cycle-by-cycle basis, To the electric power service company server through the network 500 (S210).

FIGS. 4 and 6 are cross-sectional views illustrating an artificial intelligent beveling film 100 in an artificial intelligent beveling film-based renewable energy grid system according to an embodiment of the present invention. 7 is an exploded cross-sectional view for explaining the components of the artificial intelligent sheath membrane 100 in the artificial intelligent sheath membrane-based renewable energy grid system according to the embodiment of the present invention. FIG. 8 is a block diagram specifically illustrating the components of the control unit 120 of the artificial intelligent shading film 100 in the artificial intelligent shading film-based renewable energy grid system according to the embodiment of the present invention.

4 to 7, the artificial intelligent shading film 100 includes a curved solar cell array module 110, a control unit 120, a membrane structure module 130, and a supporting member 140 .

The curved solar cell array module 110 has a cover 111 in a waterproof and dustproof coating state in order to prevent external dust and the like from sitting on the condensing efficiency type lens 112 and lowering the efficiency of light condensation, An artificial intelligent shading film 100 (see FIG. 1) including an efficient lens 112, a light condensing space 113, a curved solar cell array 114, a curved solar cell array body 114a, ).

Here, the cover 111 is shown as a planar structure. However, the cover 111 may be formed as a dome-shaped structure according to another embodiment of the present invention, and may be formed as a replaceable type that can be replaced periodically, .

Accordingly, the curved solar cell array module 110 uses the condensing efficiency type lens 112, which can be composed of a curved lens whose upper and lower surfaces are curved, After the divergence takes place in the light collecting space 113, a plurality of solar cells at the lower end are curved in cross-section in the downward direction, and n × m Can be dispersed in the entire area of the curved solar cell array 114, which is an aggregate of each curved solar cell 114u formed in the structure (n and m are two or more natural numbers different from each other).

The maximum vertical length on both sides of the condensing efficiency type lens 112 is L1 and the maximum vertical length on both sides of the entire curved solar cell array 114 and the curved solar cell array body 114a is L2, ) Of the curved solar cell array module 110 in the state that the center longest vertical length of the curved solar cell array module 110 is L3 and the length relation ratio is L1: L2: L3 = 1.2: 1: The ratio of the relationship between R1 and R2 is R1: R2 = 1: 1, and the curvature of the upper surface and the lower surface of the condensing efficiency type lens 112, which is a curved lens, It can be seen that the light-collecting efficiency is excellent in the range of 1.18 to 1.21 as compared with the case of the other embodiments.

That is, in Table 1 below, the relative electric energy filling rate is expressed relative to the value of R1: R2 = 1: 1 in the state of L1: L2: L3 = 1.2: 1: 0.7, , It was found that when the ratio of R1: R2 is 1: 1.18 to 1.21, which is the ratio of the ratio between R1 and R2, the filling rate is lowered.

division R1: R2 Relative electric energy charge rate Test Example 1 1: 1.15 1.05 Test Example 2 1: 1.16 1.03 Test Example 3 1: 1.17 1.12 Test Example 4 1: 1.18 1.23 Test Example 5 1: 1.19 1.34 Test Example 6 1: 1.20 1.28 Test Example 7 1: 1.21 1.45 Test Example 8 1: 1.22 1.25 Test Example 9 1: 1.23 1.15 Test Example 10 1: 1.24 1.11 Test Example 11 1: 1.25 1.08

The upper surface of the curved solar cell array 114 is superimposed on the curved surface of the curved solar cell array 114 and the lower surface of the curved solar cell array 114 is stably laid on the plane of the first heat insulating panel 115 The curved solar cell array body 114a may be formed of a conductive material so as to have a heat radiation function.

The first heat insulating panel 115 is located below the curved solar cell array body 114a so that when the curved solar cell array module 110 is in contact with the control unit 120, And to prevent the heat from being transmitted.

The membrane structure module 130 may include a Peltier element array 131, a heat absorbing tube 132, a second adiabatic panel 133, a foldable sheath membrane 134 and a membrane structure body 135.

The Peltier element array 131 is an aggregate of the Peltier elements 131u formed in an LxK lattice structure (L and K are equal to or different from each other) and can provide light condensing efficiency dispersed over the entire area.

The Peltier element array 131 is converted from the condensed energy to electric energy from the curved solar cell array 114 under the control of the control unit 120 and is cooled or heated using the electric energy stored in the rechargeable battery 125 Can be performed.

The heat absorbing pipe 132 is preferably formed as a functional component, but it is preferably provided, and the heat absorbing pipe 132 is formed on the upper surface of the Peltier element array 131 and externally supplied heat transfer liquid or water flows, When the lower Peltier element array 131 performs the downward cooling function according to the flow of the heat transfer liquid or the water, the Peltier element array 131 performs the heat generating function in accordance with the heat output upward, In the case where the heating function is performed downward, the cooling function is performed in accordance with the cooling that is output upward, thereby providing a heating or cooling function for recycled water or domestic water within the complex where the plurality of artificial intelligent shading films 100 are formed .

The second adiabatic panel 133 is positioned above the heat absorber 132 and functions to increase the heat transfer efficiency of the heat absorber 132 when performing a heat or cooling function of the heat absorber 132, And functions to prevent thermal energy or cooling energy from being transmitted to the contact surface when the device unit 120 and the membrane module 130 are in contact with each other at the upper and lower portions.

The folding canopy membrane 134 may be angled with the membrane structure body 135 such as an angle adjustment in the horizontal, upward, and downward directions according to the shading membrane drive unit 134a for performing angle adjustment.

For this purpose, the foldable canopy membrane 134 may be formed at each end in the longitudinal direction, or at each corner or edge region when the membrane structure body 135 is a rectangular parallelepiped. In the case where the membrane structure body 135 is cylindrical, Four ends spaced 90 degrees apart from each other on the horizontal plane, eight spacers spaced 45 degrees apart on the horizontal plane, and other variable numbers. Furthermore, as the shape or structure of the membrane structure body 135, the rectangular parallelepiped or cylindrical structure is merely an example, and may be formed in another cylindrical shape.

The support part 140 is formed in a structure in which the curved solar cell array module 110, the control device part 120 and the film structure module 130 are sequentially stacked from the top to the bottom, .

In addition, in another embodiment of the present invention, each strut of the support portion 140 includes a first height adjustment stage 141 for adjusting the space between the curved solar cell array module 110 and the control unit 120, And a second height adjustment stage 142 for adjusting a space between the controller unit 120 and the membrane module 130. The height adjustment unit 142 adjusts the height And the height can be adjusted.

8, the control unit 120 includes a sensor module 121, an I / O interface 122, a control unit 123, a storage unit 124, a rechargeable battery 125, a transceiver unit (not shown) 126).

The control unit 123 may include a power supply module 123a, a sensing module 123b, a winging film control module 123c, a temperature control module 123d, a season / day / night control module 123e, 123f.

The power supply module 123a is connected to the charge battery 125 of the control unit 120 from the curved solar cell array module 110 via the I / O interface 122, And performs control on the curved solar cell array 114 of the cell array module 110.

Thereafter, the power supply module 123a supplies power to the sensor module 121, the I / O interface 122, the control unit 123, and the storage unit 124 using the electric energy supplied to the rechargeable battery 125 .

The sensing module 123b receives the current temperature measurement value and the roughness measurement value from the temperature sensor 121a and the illuminance sensor 121b constituting the sensor module 121, (A natural number of 2 or more) temperature range from the storage unit 124 and extract the illuminance range from the storage unit 124 in steps (1 to j steps, j is a natural number of 2 or more).

Then, the sensing module 123b calculates the number and / or the number of the Peltier elements 131u to be controlled among the Peltier element arrays 131 according to the downward cooling adjustment strength value of the Peltier element array 131 matched with the plurality of stepwise temperature ranges. Or the temperature control information corresponding to the area information.

In addition, the sensing module 123b may extract angular adjustment information of the folding orifice film 134 matched with a plurality of stepwise illuminance ranges.

The shading film control module 123c performs angle adjustment of the folding shading film 134 according to the angle adjustment information received from the sensing module 123b. That is, the shading film control module 123c controls the shading film driving section 134 to drive the folding shading film 134 in accordance with, for example, the downward angle BA, the horizontal angle HL, and the upward angle UA, 134a. ≪ / RTI >

The temperature control module 123d controls the number of the Peltier elements 131u to be controlled and / or the downward cooling function for the area in the Peltier element array 131 or the downward cooling function for the Peltier element array 131u according to the temperature control information received from the sensing module 123b. And can control the I / O interface 122 to control the operation of the heating function.

The control module 123e for each season / day and night accesses an external server providing date and time information and weather information including a meteorological service server connected to the network through the transceiver 126, and receives the date and time information and the weather information And can adjust the angle of the folding orifice 134 according to the received date and time information.

In other words, the control module 123e for each season / day and night controls the shading film control module 123c to control the angle of the folding shading film 134 at a downward angle when the date information is late spring, The position information of the sun, the position information of the artificial intelligent shading film 100, and the orientation information of each folding shading film 134 are extracted from the storage unit 124 , It is possible to perform the angle adjustment only on the folding canopy membrane 134 in the strong direction of sunlight.

More specifically, the season / day / night control module 123e analyzes the position of the sun according to each date and time, and determines whether the sunlight is relatively strong in the plurality of foldable canopy films 134 It is possible to adjust the upward angle of the folding canopy 134 close to the sun, and the sunlight illuminance information according to the position and date and time of the analyzed sun when the upward angle is analyzed for control, Based information collection server.

The human body sensing type control module 123f controls the human body sensor 121c constituting the sensor module 121 to detect the temperature of the membrane structure module 130 under the solar cell array- And a horizontal surface on which the solar cell array-based temperature control type sheath film device 100 is installed.

To this end, the human body sensor 121c is vertically and horizontally matched with each Peltier element 131u constituting the Peltier element array 131 of the membrane module 130 formed above the horizontal surface of the canopy space, Or a structure in which each Peltier element 131u is matched with a region of the adjacent Peltier element 131u in a 1: 1 manner.

Here, the area constituted by the adjacent Peltier elements 131u may be artificially divided unit information to provide a cooling or heating function for one person.

In another embodiment of the present invention, the human body detecting sensor 121c is formed by a plurality of cell-unit infrared sensor attached to a panel that crosses between the pillars constituting the supporting part 140 using a separate panel Or may be formed by removing the Peltier element 131u in the central region of the Peltier element array 131 or by an imaging device which is heat-treated as a part of the Peltier element 131u.

Accordingly, when the human body detection sensor 121c is formed by the camera, the region where the human body is located through the image capturing can be detected based on the image recognition.

With this configuration, the human-body-sensing control module 123f can recognize the coordinates or the area where the human body is recognized from the human body detection sensor 121c or recognize at least one human body.

The human body detection type control module 123f controls the number of Peltier elements 131u to be controlled and / or the downward cooling function or the downward heat generation function for the area of the Peltier element array 131, O interface 122 to control the operation of the Peltier element array 131. The controller 130 controls the I / O interface 122 to control the human recognition coordinates or area O interface 122 to control the operation of the downward cooling function or the downward heat generating function only with respect to the number of the Peltier elements 131u matched with the Peltier element 131u.

On the other hand, the human-body-sensing control module 123f receives the human-recognized coordinate or area in real time, and when it enters the border area within the awning space for a preset time in the border area in the awning space, After the extraction, if the folding shade film 134 formed at a position matched with the direction information is folded downward or upward, the shading film control module 123c and the season / O interface 122 to control the operation of the shading film control module 123c through a request to the day / night control module 123e.

As described above, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms have been used, they have been used only in a general sense to easily describe the technical contents of the present invention and to facilitate understanding of the invention , And are not intended to limit the scope of the present invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

1: Smart grid unit
100: Artificial intelligent canopy membrane
110: Curved solar cell array module
111: cover
112: condensing efficiency type lens
113: condensing space
114: Curved solar cell array
114a: Curved solar cell array body
115: first insulating panel
120:
121: Sensor module
122: I / O interface
123:
123a: power supply module
123b: sensing module
123c: Shade film control module
123d: Temperature control module
124:
125: Rechargeable battery
130: membrane structure module
131: Peltier element array
132: Heat absorber
133: Second insulation panel
134: folding canopy membrane
135: membrane structure body
140: The housewife
300:
400: Electric charging station
500: Network
600: Renewable energy grid server

Claims (2)

A smart grid unit 100 composed of a plurality of artificial intelligent shading films 100, a meter probe 300, an electric charging station 400 and transmission lines 2 connected to the artificial intelligent shingles 100 and the electric charging station 400 1) is a set of at least one smart grid unit (1); A renewable energy grid server 600 connected to each smart grid unit 1 by a network 500; And further comprising an LBS server, a power service provider server, and an administrator terminal, the intelligent canopy-based renewable energy grid system comprising:
The renewable energy grid server 600 includes a communication unit 610, a smart grid platform 620, and a database 630,
The smart grid platform 620,
A plurality of artificial intelligent shingles 100 assigned to each inspection terminal 300 from each "meter reading terminal 300" of each smart grid unit 1 constituting a set of Smart Grid units 1 The communication power control unit 610 controls the communication unit 610 to receive the " power energy information "filled in the electric charging station 400 via the transmission line 2, in real time via the network 500, A big data collection module 621 for storing the identification number, location information, zone information and real time power energy information of each meter reading terminal 300 in a database 630;
The communication unit 610 is controlled to request the power energy information provided for each rechargeable battery 125 of each of the plurality of artificial intelligent shading films 100 managed by the respective meter reading terminals 300 through the network 500 When the power energy information between the artificial intelligent shading films 100 in the same direction or within a predetermined position range is different by more than a predetermined error range, The control unit 610 controls the communication unit 610 to transmit the real-time power energy information of the target artificial intelligent shine film 100, which has been requested to be inspected, to the manager terminal through the controller 500, A condensing efficiency type lens 112, a condensing space 113, a curved solar cell array 114, a curved solar cell array body 114a, and a first heat insulating panel (not shown) 115) A per-zone power measurement module 622 that allows for an on-board check to be performed;
The control unit 610 controls the communication unit 610 to receive an electric charging station information request from the electric vehicle terminal 700 through the network 500 and displays the terminal number, the location information, and the electric power of the electric vehicle terminal 700 that transmitted the electric charging station information request, The control unit 610 controls the communication unit 610 to request and receive the charging request amount through the network 500 to the electric vehicle terminal 700 and then transmits the charging request amount to the meter probe terminal 700 having the zone information closest to the received electric vehicle terminal 700 300 extracted from the database 630 and extracts the inspected power energy information of the electric charging station 400 managed by the inspected terminal 300. When the extracted electric energy information requests the electric charging station information It is analyzed whether it is sufficient to accommodate the electric charge requirement of the electric vehicle terminal 700 and if it is analyzed that it is not sufficient to accommodate the electric charge requirement of the electric vehicle terminal 700, Extracts the identification number of the inspection terminal 300 having the location information of the aircraft terminal 700 and the adjacent area information next and extracts the electric energy information of the electric charging station 400 managed by the inspection terminal 300 And then analyzes the electric charging station 400 information which is analyzed to be sufficient to accommodate the electric charging demand and the information of the electric charging station 400 A power mediation module 623 provided to the terminal 700; And
Controls the communication unit 610 to receive the electric charge from the electric vehicle terminal 700 and to receive payment information according to the electric charge amount, and provides the electric energy information for each zone to the power service company server through the network 500 on a cycle- Controls the communication unit 610 and controls the communication unit 610 to transmit a charge reduction request proportional to the accumulated power energy information to the power supply company server through the network 500 for the home or industrial complex corresponding to each zone An electricity bill settlement module 624 for each zone; And a second electrode,
The power mediation module 623,
In analyzing whether the electric power energy information is sufficient to accommodate the electric charge requirement of the electric vehicle terminal 700 requesting the electric charging station information, it is necessary to determine whether the electric charging demand of the electric vehicle terminal 700 and the real- Information on the electric vehicle terminal 700 is compared with the location information of the electric charging station 400 or the meter-reading terminal 300 and the position information of the electric vehicle terminal 700 when the real- , And when there is no real-time electric charging request by another electric vehicle terminal, it is analyzed that it is sufficient.
The method according to claim 1,
The metering terminal 300 for each zone checks the charged power energy information of the electric charging station 400 that it manages and then transmits the meter energy information to the renewable energy grid server 600 through the network 500. [ To a new energy-saving grid system based on artificial intelligence.

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