KR20220028616A - Art work realization system using building-integrated photo voltaic - Google Patents

Abstract

The present invention relates to a system for implementing a work of art using a building-integrated photovoltaic (BIPV) module, which can enhance the value of a building by installing the BIPV module on the exterior of the building in the form of a work of art such as Piet Mondrian's. A user requests the installation of a BIPV module online via a network using a user terminal, selects a work of Mondrian as an installation shape, and completes making a reservation for installation of the BIPV module based on a simulation result. When the installation of the BIPV module is requested through the user terminal and the work of Mondrian is selected, a photovoltaic module work server generates installation information for the BIPV module according to the building information and the work of Mondrian. When installation reservation information is generated from the user terminal, the photovoltaic module work server transmits the installation information to a terminal of a photovoltaic module installation company and requests the installation of the BIPV module.

Description

Art work realization system using building-integrated photo voltaic

The present invention relates to a system for implementing works of art using a building-integrated photovoltaic module. In particular, when a building-integrated photovoltaic (BIPV) module is installed on the exterior of a building, it is a work of art such as Piet Mondrian. It relates to an art work realization system using a building-integrated photovoltaic module that can be installed to improve aesthetics and improve the value of a building at the same time.

In general, Building Integrated Photovoltaic (BIVP) is a technology that applies solar cells as building materials and uses them as exterior materials for buildings. The building-integrated photovoltaic module integrates and applies a photovoltaic (PV) module to a building, and is used in various ways, such as curtain walls, awnings, roof tiles, and exterior materials.

When a building-integrated photovoltaic module is used as an exterior material for a building, a building-integrated photovoltaic module of various shapes is required depending on the design of the building. In this case, if you want to install a building-integrated photovoltaic module in a corner or a round part, which is a special part of the exterior of a building, each form is diverse, and in some cases, a customized building-integrated photovoltaic module is separately produced and used.

In fact, the case in which a customized building-integrated photovoltaic module is installed depends on the scope of application among the parts occupied by the entire building-integrated photovoltaic module. There is also the need to install the solar power module in a part with a special shape, such as a corner or round. In other words, rather than generating electricity by photovoltaic power generation, design harmony with other parts as an exterior material of a building had to be considered. became a matter

Therefore, it is possible to reduce costs while achieving design harmony with other parts by using a custom building-integrated photovoltaic power generation dummy module with a model for price ratio rather than using an expensive custom building-integrated photovoltaic power module as in the prior art. And it can save manufacturing time, so a customized building-integrated photovoltaic power generation dummy module has also been developed and used.

However, when installing a building-integrated photovoltaic power module as a building exterior material using such a customized building-integrated photovoltaic dummy module, there is an advantage in handling special environments such as corners, but using this to improve the aesthetics of the entire building has limitations.

On the other hand, a conventional technique for using a building-integrated photovoltaic module as a finishing material for the exterior wall of a building is disclosed in <Patent Document 1> below.

The prior art disclosed in <Patent Document 1> prepares a horizontal frame and a vertical frame and installs it on any one of the exterior wall of a building, the roof of the building, and the roof of the structure, and the horizontal frame and

The pressing member is fastened between the solar cell modules in any one of the vertical frames, and the wire drawn out from the junction box of the solar cell module is passed through the pressing member to wire and connect. Through this, not only is it convenient to maintain the solar cell module that produces electric energy, but also the wires drawn out from the junction box are wired and connected in the pressure member installed on either the horizontal frame or the vertical frame, so that the outer wall of the building, the roof of the building, and the structure are connected. It can be easily installed on the roof of

In this prior art, a building-integrated photovoltaic module can be conveniently installed on the exterior wall of a building using a horizontal frame and a vertical frame. There are limits.

In particular, the prior art has a limitation in implementing a single work of art by integrating a building-integrated solar module into several buildings.

Korean Patent Laid-Open Patent No. 10-2011-0045523 (published on May 4, 2011) (Building-integrated photovoltaic exterior material installation method)

Therefore, the present invention is proposed to solve various problems occurring in the case of using the general building-integrated photovoltaic (BIPV) module as described above as a building exterior material and in the prior art, and building-integrated photovoltaic (building-integrated photovoltaic) When installing the BIPV) module on the exterior of a building, it is installed as a work of art like Piet Mondrian to improve aesthetics and enhance the value of the building at the same time. Its purpose is to provide

In order to achieve the above object, "a system for implementing works of art using a building-integrated solar module" according to the present invention,

a user terminal that requests installation of a building-integrated photovoltaic module online through a network, selects a Mondrian work as an installation shape, and processes a reservation for installation of a building-integrated photovoltaic module based on the simulation result;

When the installation of the building-integrated solar module is requested through the user terminal and a Mondrian work is selected, installation information of the building-integrated photovoltaic module is generated according to the building information and the Mondrian work, and installation reservation information is generated from the user terminal a solar module work server that transmits installation information to the terminal of a solar module installation company and requests installation of a solar module;

It is characterized in that it comprises a solar module installer terminal that receives the installation information transmitted from the solar module work server, stores and displays the received installation information on the screen.

In the above, the photovoltaic module work server is characterized in that it acquires the building information of the target building for which installation of the building-integrated photovoltaic module is requested from the user terminal or automatically directly from the building server through the network.

In the above photovoltaic module work server, when the installation of the building-integrated photovoltaic module is requested by the user terminal, it is characterized in that it comprises an art guide for guiding the Mondrian work as a work of art to the user terminal.

The photovoltaic module work server in the above is characterized in that it comprises a photovoltaic module selection unit that selects the number of building-integrated photovoltaic modules using the Mondrian work selected from the user terminal and the acquired building information.

In the above, the photovoltaic module work server installs the photovoltaic module in the building through augmented reality using the number information of the selected building-integrated photovoltaic module, the selected Mondrian work, and the acquired building information to perform a photovoltaic module installation simulation, , characterized in that it includes a solar module installation simulation unit that generates a simulation result.

In the above, the photovoltaic module work server includes a simulation result transmission unit that transmits a simulation result file with improved security by inserting print prevention and download prevention information into the simulation result generated by the solar module installation simulation unit to the user terminal characterized in that

In the above photovoltaic module work server, it is characterized in that it comprises a control unit for automatically canceling the login if there is no information exchange for a certain period of time after the user terminal is connected.

In the photovoltaic module work server, when a reservation and payment are made through the user terminal, a photovoltaic module installation information generating unit for generating photovoltaic module installation information based on the simulation result file; and a photovoltaic module installation information transmitter for transmitting the photovoltaic module installation information generated by the photovoltaic module information generator to a photovoltaic module installer terminal through a network.

According to the present invention, when a building-integrated photovoltaic module (BIPV) is installed on the exterior of a building, it is installed as a work of art such as Piet Mondrian, thereby improving aesthetics and improving the value of the building.

In addition, according to the present invention, the user can pre-verify the building-integrated photovoltaic module through simulation before the actual building-integrated photovoltaic module is installed in the building, thereby preventing fertilization that may occur after installing the building-integrated photovoltaic module in the building has a preventable effect.

In addition, according to the present invention, since the solar module constructor installs the building-integrated solar module based on the solar module installation information simulated in advance for the building, the time to install the building-integrated solar module in the building is reduced. It is possible to save money, and as a result, it is possible to reduce the installation cost of the building-integrated photovoltaic module to the user.

1 is a schematic configuration diagram of a system for implementing a work of art using a building-integrated solar module according to the present invention;
Figure 2 is a block diagram of an embodiment of the solar module work server of Figure 1;
Figure 3 is an example of Mondrian works guided to the user terminal in the present invention,
Figure 4 is an exemplary view in which the building-integrated solar module is implemented in a building according to the Mondrian work selected by the user in the present invention.

Hereinafter, an art implementation system using a building-integrated solar module according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The terms or words used in the present invention described below should not be construed as being limited to conventional or dictionary meanings, and the inventor may appropriately define the concept of terms in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents and It should be understood that there may be variations.

1 is a schematic configuration diagram of an art work implementation system using a building-integrated photovoltaic module according to a preferred embodiment of the present invention, a user terminal 100, a photovoltaic module work server 200, and a photovoltaic module installer module ( 300) is included.

The user terminal 100 requests the installation of a building-integrated photovoltaic module to the photovoltaic module work server 200 online through a network, selects a Mondrian work as an installation shape, and based on the simulation result, a building-integrated photovoltaic module It is responsible for handling the installation reservation of The user terminal 100 is a terminal used by a user, and may be implemented as a mobile device such as a smart phone, a personal computer (PC), or the like.

After accessing the photovoltaic module work server 200 using the user terminal 100, online access, member registration, request, reservation, and payment are made. A user can request, reserve, and pay for installation of a building-integrated photovoltaic module while registered as a member, and can also perform installation request, reservation, and payment in a non-member state without a log-in process. When a request is made as a non-member, it is inconvenient because more information has to be input than that of a member.

The solar module work server 200 is requested to install a building-integrated photovoltaic module through the user terminal 100, and when a Mondrian (Piet Mondrian, western painter) work is selected, the building-integrated building-integrated module according to the building information and Mondrian work It generates installation information of the solar module, and when installation reservation information is generated from the user terminal 100, the installation information is transmitted to the solar module installation company terminal 300 to request the installation of the solar module.

The photovoltaic module work server 200 may obtain building information of a target building for which installation of a building-integrated photovoltaic module is requested from the user terminal 100 or automatically directly from a building server through a network.

Here, the building server may be a portal server such as Naver or Google, a real estate server, or the like that can provide building information.

As shown in FIG. 2, the solar module work server 200 includes a member registration unit 201 that registers a user as a member based on user information provided through the user terminal 100, the user terminal 100 ), when the installation of the building-integrated solar module is requested by the art work guide 202 that guides the Mondrian work as a work of art to the user terminal 100, download the building photovoltaic application to the user terminal 100 and a building photovoltaic application providing unit 203 .

In addition, the photovoltaic module work server 200 is a user information receiving unit 204 that receives the building information and installation location information transmitted from the user terminal 100, and the artwork guided to the user terminal 100. and a work selection unit 205 for selecting a Mondrian work according to work information selected by the user through the user terminal 100 .

In addition, the photovoltaic module work server 200 includes a photovoltaic module selection unit 206 that selects the number of building-integrated photovoltaic modules using the selected Mondrian work and the acquired building information.

In addition, the photovoltaic module work server 200 uses the number information of the selected building-integrated photovoltaic module, the selected Mondrian work, and the acquired building information, and installs the photovoltaic module in the building through augmented reality. and a solar module installation simulation unit 207 that performs a simulation and generates a simulation result.

In addition, the photovoltaic module work server 200 inserts print prevention and download prevention information into the simulation result generated by the photovoltaic module installation simulation unit 207 to provide a simulation result file with improved security to the user terminal ( 100) includes a simulation result transmission unit 208 that transmits the result, and a control unit 210 that automatically cancels the login if there is no information exchange for a certain period of time after the user terminal 100 is connected.

In addition, the photovoltaic module work server 200 is a photovoltaic module installation information generating unit that generates photovoltaic module installation information based on the simulation result file when reservation and payment are made through the user terminal 100 ( 211), including a photovoltaic module installation information transmitting unit 212 for transmitting the photovoltaic module installation information generated by the photovoltaic module information generating unit 211 to the photovoltaic module installer terminal 300 through a network do.

In addition, the photovoltaic module work server 200 includes a database (DB) 213 in which a building photovoltaic application, member information, Mondrian work information, augmented reality implementation program, simulation program, control program, and the like are stored.

The solar module installer terminal 300 receives the installation information transmitted from the solar module work server 200, stores the received installation information, and plays a role of displaying it on the screen. The solar module installer terminal 300 may be implemented as a mobile device or personal computer carried by the solar module installer user.

The operation of the art work realization system using the building-integrated solar module according to the present invention configured as above will be described in detail as follows.

First, a user who wants to install a building-integrated photovoltaic module as an exterior material in his/her own building (building, apartment, etc.) connects to the photovoltaic module work server 200 using his/her own user terminal 100. . Here, it is assumed that the user terminal 100 is a mobile device.

Next, the building photovoltaic application providing unit 203 of the photovoltaic module work server 200 downloads the photovoltaic module application to the connected user terminal.

A user who has downloaded the solar module application installs and runs the solar module application, provides information on the executed solar module application, requests member registration, or accesses as a non-member.

Here, member registration is performed in the same manner as the member registration procedure performed on a general network.

When member registration is requested, the member registration unit 201 of the solar module work server 200 registers member information in the database 213 and registers the user as a member.

A user requests installation of a building-integrated solar module by using the user terminal 100 after completing membership registration or in a non-member state.

In this case, the user uses the user terminal 100 to provide information about a building where a building-integrated solar module is to be installed (a photograph of an exterior of a building, address information, etc.) and installation information about where the user wants to install it. If necessary, the user may provide only address information and installation location information.

When the building information and installation information are transmitted from the user terminal 100 , the user information receiving unit 204 receives it, matches the user information (member information) and registers it in the database 213 .

Here, when the user provides only address information as building information, the control unit 210 of the photovoltaic module work server 200 connects to a building server that provides building information, that is, a portal server such as Naver or Google, and uses the address information. Building information may be acquired, or building information may be automatically obtained directly through the corresponding address information by accessing a real estate server, etc. In this case, it is possible to improve the inconvenience of the user directly collecting and acquiring building information, and generating and transmitting the information in the form of a file.

Thereafter, the user selects the Mondrian work guided as shown in FIG. 3 through the work of art guide 202 through the user terminal 100 . Here, the present invention has described only the Mondrian work as a work of art, but the present invention is not limited thereto. Allows selection of works of art.

The work selection unit 205 of the photovoltaic module work server 200 selects the Mondrian work as a work of art according to the work information selected through the user terminal 100 .

Next, the photovoltaic module selection unit 206 of the photovoltaic module work server 200 selects the number of building-integrated photovoltaic modules using the selected Mondrian work and the acquired building information. For example, the installation area is calculated based on the installation location information of the building information, and when the Mondrian works are implemented in the calculated installation area, the number of required building-integrated photovoltaic modules is extracted. Here, although the size of the building-integrated photovoltaic module varies, since the size of the building-integrated photovoltaic module to be used is predetermined, the number of the building-integrated photovoltaic module to be used can be easily extracted compared to the area. Here, it is assumed that the building-integrated photovoltaic module is a color photovoltaic module that can implement color. The color and number of building-integrated solar modules are selected according to the color and location of each color of Mondrian's work.

Then, the photovoltaic module installation simulation unit 207 of the photovoltaic module work server 200 uses the number information of the selected color building-integrated photovoltaic module, the selected Mondrian work, and the acquired building information through augmented reality. A photovoltaic module installation simulation is performed by installing a photovoltaic module in a building. In other words, through augmented reality, a color solar module is installed in a building in the form of a Mondrian artwork to derive simulation results. Since the simulation is performed with augmented reality, the same result can be obtained as if a color building-integrated solar module was installed in an actual building. 4 is an example of a building simulation result in which a building-integrated solar module simulated by augmented reality is shaped.

Next, the simulation result transmission unit 208 of the solar module work server 200 improves security by inserting print prevention and download prevention information into the simulation result generated by the solar module installation simulation unit 207 A simulation result file is created. Then, the simulation result file in which the security information is inserted is transmitted to the user terminal 100 .

The user displays the simulation result on the screen through the user terminal 100 . Here, simulation results cannot be saved or printed due to the download protection function and the print protection function. The print prevention function and the download prevention function can be implemented in such a way that the print button or the download button is not displayed on the screen. This print prevention function and download prevention function are to prevent users from stealing augmented reality simulation results.

Therefore, the user sees the simulation result shown on the screen, and if he is satisfied, he processes the reservation and payment. If he wants to see another work, he selects another Mondrian work and requests a re-simulation.

As such, the present invention enables the user to check in advance in the same way as the solar module installed in the actual building through augmented reality simulation before installing the building-integrated solar module, thereby preventing disputes that may occur later. be able to

Here, the control unit 210 of the solar module work server 200 automatically releases the login if there is no information exchange with the user terminal 100 for a preset period of time after transmitting the augmented reality simulation result to the user. This is to prevent users from stealing the augmented reality simulation results.

When the user is satisfied with the augmented reality simulation result, the user checks the payment cost, and processes reservation and payment through the input device.

Here, for the reservation of the building-integrated solar module, the control unit 210 may provide a reservationable date based on reservation information stored in the database 213 . This is to consider the manpower of solar module construction companies. The reservation and payment processing unit 209 of the solar module work server 200 stores the reservation information transmitted from the user terminal 100 in the database 213, and performs payment processing in conjunction with a VAN company. The payment processing information is registered in the database 213 and transmitted to the user terminal 100 at the same time, so that the user can check the payment information in real time.

When reservation and payment are made through the user terminal 100 , the solar module installation information generating unit 211 generates solar module installation information based on the simulation result file. Here, the solar module installation information may include augmented reality simulation information, the number of color building-integrated solar modules, installation reservation information, Mondrian work information, and the like.

Next, the solar module installation information transmission unit 212 transmits the solar module installation information generated by the solar module information generation unit 211 to the solar module installation company terminal 300 through the network.

The solar module construction company observes the installation reservation date based on the received solar module installation information, and installs the building-integrated solar module on the installation reservation date.

Here, since the solar module construction company knows the installation information of the solar module in advance, there is no need to design according to the installation of the solar module, so the design conception time can be shortened. can do. As a result, it is possible to promote the convenience of construction of the building-integrated solar module and shorten the construction time.

Although the invention made by the present inventor has been described in detail according to the above embodiment, the present invention is not limited to the above embodiment and it is common knowledge in the art that various changes can be made without departing from the gist of the present invention. It is self-evident to those who have

100: user terminal
200: solar module work server
201: Member Register
202: Art Information Department
203: Building Solar Application Provider
204: user information receiving unit
205: work selection unit
206: solar module selection unit
207: solar module installation simulation unit
208: simulation result transmission unit
209: Reservation and payment processing unit
210: control unit
211: solar module installation information generation unit
212: solar module installation information transmission unit
213: database (DB)

Claims (8)

As a system for realizing works of art using a building-integrated photovoltaic module (BIPV),
a user terminal that requests installation of a building-integrated photovoltaic module online through a network, selects a Mondrian work as an installation shape, and processes a reservation for installation of a building-integrated photovoltaic module based on the simulation result;
When the installation of the building-integrated solar module is requested through the user terminal and a Mondrian work is selected, installation information of the building-integrated photovoltaic module is generated according to the building information and the Mondrian work, and installation reservation information is generated from the user terminal a solar module work server that transmits installation information to the terminal of a solar module installation company and requests installation of a solar module; and
Receiving installation information transmitted from the solar module work server, and storing and displaying the received installation information on the screen, a solar module installer terminal comprising a building-integrated solar module art implementation system .
The method according to claim 1, The photovoltaic module work server is a building-integrated building, characterized in that the building information of the target building for which installation of the building-integrated photovoltaic module is requested is obtained from the user terminal or automatically directly obtained from the building server through the network. An art work realization system using solar modules.
The method according to claim 1, The solar module work server, when the installation of the building-integrated photovoltaic module is requested by the user terminal, the building characterized in that it comprises an art guide that guides the Mondrian works to the user terminal as works of art. An art work realization system using an integrated solar module.
The method according to claim 1, The photovoltaic module work server is a building-integrated sun, characterized in that it comprises a photovoltaic module selection unit for selecting the number of building-integrated photovoltaic modules using the Mondrian work selected from the user terminal and the acquired building information A system for realizing works of art using optical modules.
The method according to claim 1, The photovoltaic module work server installs a photovoltaic module in a building through augmented reality using the number information of the selected building-integrated photovoltaic module, the selected Mondrian work, and the acquired building information, and simulates the photovoltaic module installation and a solar module installation simulation unit that performs and generates a simulation result.
The simulation result of claim 5, wherein the photovoltaic module work server transmits a simulation result file with improved security by inserting print prevention and download prevention information into the simulation result generated by the photovoltaic module installation simulation unit to the user terminal Art implementation system using a building-integrated solar module, characterized in that it includes a transmission unit.
The system according to claim 1, wherein the photovoltaic module work server includes a control unit that automatically cancels the login if there is no information exchange for a certain period of time after the user terminal is connected. .
The method according to claim 1, The photovoltaic module work server, when a reservation and payment is made through the user terminal, a photovoltaic module information generating unit that generates photovoltaic module installation information based on the simulation result file; Art using a building-integrated photovoltaic module, characterized in that it comprises a photovoltaic module installation information transmitter for transmitting the photovoltaic module installation information generated by the photovoltaic module information generator to a photovoltaic module installer terminal through a network work implementation system.

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