KR102105202B1 - Roof awning apparatus - Google Patents

Abstract

The present invention relates to a roof awning system, which is installed at an outdoor place to provide shade, is configured such that a roof can be opened and closed or tilted, and can calculate whether a roof wing part is opened and closed or an opening and closing degree through big data analysis. The roof awning system includes: a roof frame part formed in a square shape; a roof wing part connected along an inner side of the roof frame part so that the roof is formed and opening and closing an inner space of the roof frame part while being tilted and slid; and a support frame part installed on each edge of lower sides of the roof frame part to support the roof frame part.

Description

Roof awning device {ROOF AWNING APPARATUS}

The present invention relates to a roof awning device, and more specifically, it is installed in an outdoor place to provide a shade, is configured to enable roof opening or tilting, and calculates whether the roof wing is opened or closed through big data analysis. It relates to a loop awning system including a loop awning device implemented to enable.

Coffee shops and restaurants are widely used because of their awning devices that provide shade to eat food outdoors.

In general, the awning device was able to provide a shade by cutting a long rebar pipe to a certain length and welding each fastening portion to form a frame, and covering a tent or plate on the top of the pipe frame.

However, in the case of the conventional awning device, since the fastening portion is fixed by a welding method, the working time for assembling the frame has to be lengthened, and the upper sunshade film is assembled by fixing it by winding it with a frame, such as a string, to fix it in winter. As shown in the above, if the sunshade is unnecessary, there is a inconvenience in that it is necessary to repeat the process of disassembly and assembly of the sunshade.

In addition, in order to fasten the frames of 3 m or more to each other by welding method, two workers lifted and fixed the long frames to the installation height, and the other worker had to weld the welding machine, so there was a problem of excessive labor costs.

On the other hand, the above-mentioned background technology is the technical information acquired by the inventor for the derivation of the present invention or acquired in the derivation process of the present invention, and is not necessarily a known technology disclosed to the general public before filing the present invention. .

Korea Public Utility Model No. 20-2009-0000208 Korean Registered Utility Model No. 20-0347513

One aspect of the present invention is free from sunlight, rain, snow, wind, outside air, and can utilize a driving system to use existing materials, and smart tilting and opening and closing is possible by utilizing artificial intelligence in consideration of the weather. Provided is a loop awning system that can be used, recycled, and implemented to localize materials.

In other words, through big data analysis, pedestrians taking a break in the shade formed by the present invention or temporarily avoiding rain or snow, collect and analyze search words, etc., searched through web pages, etc. Provided is a loop awning system implemented to calculate whether or not to open or close a loop wing using an analysis value calculated by using.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

A loop awning system according to an embodiment of the present invention includes a roof frame formed in a square shape; A roof wing part connected to the roof frame part to form a loop, and opening and closing the inner space of the roof frame part while tilting and sliding; And a support frame portion installed at each lower edge of the roof frame portion to support the roof frame portion.

In one embodiment, the loop frame portion, the first frame is formed extending in the front-rear direction; A second frame spaced apart from the first frame in a left-right direction and extended in a front-rear direction; A third frame extending right and left between the front end of the first frame and the front end of the second frame; And a fourth frame that is spaced apart in the front-rear direction from the third frame and extends left and right between a rear end of the first frame and a rear end of the second frame.

In one embodiment, the loop wing portion, one side is installed connected to the first frame and the other side is connected to the second frame is installed a plurality of louvers (Louver) to form one wing constituting the loop; A plurality of tilting motors connected to one side of the louver and tilting the louver clockwise or counterclockwise so as to open or shield the inner space of the roof frame portion; A plurality of links consisting of a first bar and a second bar connected in a "X" form with a tilting shaft extending from one side of the tilting motor to one side of the louver as a central axis so as to tilt the louver; A plurality of support bars installed eccentrically from the tilting shaft of the louver at one side of the louver; A plurality of connecting wires connecting the support bar and a support bar installed in another louver; It is installed in the inner space of the third frame, while winding or unwinding a chain formed from a tilting motor connected to a louver installed closest to the third frame and pulling the corresponding tilting motor in the direction of the third frame A first open / close motor; And a chain extending from a tilting motor installed in an inner space of the fourth frame and connected to a louver installed closest to the fourth frame, while pulling or unwinding the chain, pulling the tilting motor in the direction of the fourth frame. Note may include a second opening and closing motor;

In one embodiment, the first bar of the link may be connected to one end so as to be rotatable to the other end of the second bar of another link that is disposed nearby.

In one embodiment, the second bar of the link may be connected to one end so as to be rotatable to the other end of the first bar of another link that is disposed nearby.

In one embodiment, the link installed to the louver installed closest to the third frame, each end of the first bar and the second bar as the first opening and closing motor pulls the tilting motor connected to itself The other moves along the wall surface of the third frame in a direction away from each other. Accordingly, the other ends of the first bar and the second bar also open in a direction away from each other, and other louvers arranged adjacent to the louver to which they are connected are installed. Each other end of the first bar and the second bar of the other link installed to be opened in a direction away from each other may be pulled by sliding the other louvers in the direction of the louvers where they are installed.

In one embodiment, the louver, the wing body to open and close the inner space of the roof frame portion while tilting in the clockwise or counterclockwise direction; A first bending wing bent to be rounded upward from the front end of the wing body; And a second bent wing that is bent to be rounded downward from the rear end of the wing body.

In one embodiment, the first bending wing or the second bending wing, the second body of the other louver so as to prevent foreign matter from flowing between the wing body of the other louver disposed adjacent to the wing body that is contained therein The bending wing or the first bending wing may be engaged.

In one embodiment, the roof awning system according to an embodiment of the present invention, a rainwater sensor for detecting the intensity and amount of rainwater; A stop device that detects opening and closing of the wing portion of the loop; An IP camera that shoots surrounding images; A user terminal that installs a dedicated application for controlling the roof awning system, and is connected to the roof wing through a network to control opening and closing of the roof wing; And a loop control server that is connected to the roof wing or the user terminal through a network, reads whether the roof wing is opened or closed using weather public data provided by the Korea Meteorological Agency, and controls opening and closing of the roof wing. It can contain.

In one embodiment, the loop control server reads the altitude angle of the sun in real time using weather public data provided from the Korea Meteorological Administration, and one side of the louver of the loop wing portion controls the sun according to the read altitude angle of the sun. After calculating the tilting angle of the louver of the loop wing portion to prevent sunlight from entering and entering the loop wing portion, the opening and closing control signal corresponding thereto may be generated and transmitted to the loop wing portion through a network.

In one embodiment, the loop control server, by using the video information received from the IP camera, reads the number of people and the position of the people located in the shade formed by the roof wing portion, the loop wing portion The opening and closing control signal for adjusting the opening / closing degree of the loop wing portion may be generated and transmitted to the roof wing portion through a network so that the shade formed by the cover can cover both the read number of people and the location of the corresponding people.

In one embodiment, the loop control server reads the amount of snow accumulated on the upper side of the roof wing in real time using weather public data provided by the Korea Meteorological Administration, and reads that the amount of snow accumulated in the roof wing is higher than a preset height. When possible, an opening and closing control signal for tilting the louver of the roof wing portion from 90 ° to 180 ° can be generated and transmitted to the loop wing part through a network so that the snow accumulated in the roof wing part falls downward.

In one embodiment, the real-time weather information received through the network from the loop control server using a screen display or a voice output device for outputting a notification unit; may further include a.

In one embodiment, the loop control server includes: a collection management module that sets at least one collection criterion among a collection target data source module, a collection target keyword, and a collection target period; A data collection module that collects big data from the data source module and stores it in a database module according to data collection criteria set by the collection management module; A morpheme analysis module that analyzes morphemes of the big data stored in the database module, classifies each morpheme, and generates morpheme analysis data; And a data analysis module that processes the morpheme analysis data using a statistical analysis algorithm based on distributed parallel processing to calculate a statistical value and outputs a week signal according to the statistical value. By doing so, it is possible to read whether the roof wing is opened or closed.

According to one aspect of the present invention described above, it is possible to provide a variety of materials, such as aluminum, fabric, tiles, etc., and can be opened and closed quickly using a continuous opening and closing method, corrosion by ultraviolet rays No, mold growth is impossible, and it is robust and reliable from earthquakes and typhoons, etc. It provides convenience by remotely controlling the operation with a smartphone, low installation cost, semi-permanent use, and 10% recycled material It can be used to provide an effect that can provide economics.

In addition, through big data analysis, pedestrians taking a break in the shade formed by the present invention or temporarily avoiding rain or snow collect and analyze search words searched through web pages, etc., and use big data It is possible to provide an effect of providing an optimized shade or shelter to a pedestrian at the lower side of the loop generated by the present invention by calculating whether the roof wing is opened or closed using the calculated analysis value.

The effects of the present invention are not limited to the above-mentioned effects, and various effects may be included within a range obvious to those skilled in the art from the following description.

1 is a view showing a schematic configuration of a loop awning system according to an embodiment of the present invention.
2 is a view for explaining the opening and closing of the roof wing portion of FIG.
FIG. 4 is a view showing a loop frame part of FIG. 1.
5 is a view showing the roof wing of FIG. 1.
FIG. 6 is a view for explaining the tilting of the louver of FIG. 5.
7 is a view for explaining sliding movement by the link of FIG. 5.
8 is a view for comprehensively explaining the tilting and sliding movement of the roof wing of FIG. 5.
9 is a diagram illustrating a schematic configuration of a roof awning system according to another embodiment of the present invention.
10 is a view showing the support frame of FIG. 1.

For a detailed description of the present invention, which will be described later, reference is made to the accompanying drawings that illustrate, by way of example, specific embodiments in which the invention may be practiced. These examples are described in detail enough to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain shapes, structures, and properties described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. In addition, it should be understood that the location or placement of individual components within each disclosed embodiment can be changed without departing from the spirit and scope of the invention. Therefore, the following detailed description is not intended to be taken in a limiting sense, and the scope of the present invention, if appropriately described, is limited only by the appended claims, along with all ranges equivalent to those claimed. In the drawings, similar reference numerals refer to the same or similar functions across various aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 is a view showing a schematic configuration of a loop awning system according to an embodiment of the present invention.

Referring to FIG. 1, the roof awning system 10 according to an exemplary embodiment of the present invention includes a roof frame part 100, a roof wing part 200, and a support frame part 300. The loop awning system 10 may be a loop awning device, and a system including a loop awning device illustrated in FIG. 9 and a device in communication with the loop awning device may be defined as a loop awning system 20.

The roof frame 100 includes four frames forming four surfaces (that is, the first frame 110, the second frame 120, the third frame 130, and the fourth frame 140, which will be described later). It is formed in a rectangular shape by connection, and the roof wing part 200 is connected to the inner space formed by each frame, and is supported by the support frame part 300 installed at each lower corner.

The roof wing part 200 is a configuration that forms a roof of the roof awning system 10 according to the present invention, and a plurality of rows are lined up along the inside of the roof frame part 100 to form a loop, and tilting And opening and closing the inner space of the roof frame part 100 while sliding.

That is, the roof wing part 200 covers the entire inner space of the frame part 100 as shown in (a) of FIG. 2 and performs a function as a roof while being shown in FIG. 2 (b). Likewise, it is possible to open the inner space of the frame part 100 by sliding all of them to one side of the inner space of the frame part 100.

The support frame part 300 is installed at each lower edge of the roof frame part 100 to support the roof frame part 100.

The roof awning system 10 according to an embodiment of the present invention having the configuration as described above may be installed to cover a larger area by being connected to each other, and each system may simultaneously or individually open and close operations. It is possible to produce a variety of materials such as aluminum, fabric, tile, etc., and it can provide a variety of materials. It can be opened and closed quickly by using a continuous opening and closing method. Robust and reliable from typhoons, typhoons, etc., providing convenience by remotely controlling the operation with a smartphone, low installation cost, semi-permanent use, and 10% recycled material available for economics can do.

FIG. 4 is a view showing a loop frame part of FIG. 1.

Referring to FIG. 4, the loop frame unit 100 includes a first frame 110, a second frame 120, a third frame 130, and a fourth frame 140.

The first frame 110 is spaced apart from the second frame 120 and formed to extend in the front-rear direction, and one side of the louver 210 described later is connected.

The second frame 120 is spaced apart from the first frame 110 in the left-right direction and extends in the front-rear direction, and the other side of the louver 210 described later is connected.

The third frame 130 is formed to extend left and right while facing the fourth frame 140 between the front end of the first frame 110 and the front end of the second frame 120.

The fourth frame 140 is spaced apart from the third frame 130 in the front-rear direction and is formed to extend left and right between the rear end of the first frame 110 and the rear end of the second frame 120.

5 is a view showing the roof wing of FIG. 1.

Referring to FIG. 5, the roof wing part 200 includes a louver 210, a tilting motor 220, a link 230, a support bar 240, a connecting wire 250, and a first opening / closing motor ( 260) and a second open / close motor 270.

The louver 210 has one side connected to the first frame 110 and the other side connected to the second frame 120 to form a blade constituting a loop, and a tilting motor connected to one side Tilted by 220 as shown in FIG.

Referring to FIG. 6, the louver 210 may include a wing body 211, a first bending wing 212 and a second bending wing 213.

The wing body 211, while tilting in the clockwise or counterclockwise direction by the driving of the tilting motor 220, closes the inner space of the roof frame portion 100 as shown in FIG. As shown in (b) of 6, it can be opened by tilting.

The first bending wing 212 is formed to be bent to be rounded upward from the front end of the wing body 211.

The second bending blade 213 is formed to be bent so as to be rounded downward from the rear end of the wing body 211.

In one embodiment, the first bending wing 212 or the second bending wing 213 is a foreign body between the wing body 211a of itself and other wing bodies 211b of other louvers 210b disposed nearby. The second bending wing 213b or the first bending wing 212b of the other louver 210b may be engaged to prevent inflow.

The tilting motor 220 is installed connected to one side of the louver 210, and the louver 210 is clockwise or as shown in FIG. 6 so as to open or shield the inner space of the roof frame part 100. Tilt it counterclockwise.

Link 230, the tilting shaft 221 extending from one side of the tilting motor 220 to one side of the louver 210 to the center of the louver 210 so as to tilt the louver 210 is installed in the form of "X" It consists of a first bar (231) and a second bar (232).

In one embodiment, the first bar 231 of the link 230 may be connected to one end so as to be rotatable to the other end of the second bar 232 of the other link 230 that is disposed nearby.

In one embodiment, the second bar 232 of the link 230 may be connected to one end so as to be rotatable to the other end of the first bar 231 of the other link 230 that is disposed nearby.

In one embodiment, the link 230c is installed to be connected to the louver 210c installed closest to the third frame 130, the first opening / closing motor 260 grabs the tilting motor 220 installed by itself. Each end of the first bar 231c and the second bar 232c is moved in a direction away from each other along the wall surface of the third frame 130 according to the pulling, and accordingly, the first bar 231c and the second Each other end of the bar 232c is also opened in a direction away from each other, and the first bar 231b of the other link 230b is installed to be connected to another louver 210b disposed adjacent to the louver 210c to which it is installed. As each end of the second bar 232b is opened in a direction away from each other, the other louvers 210b in the order of (a), (b), and (c) of FIG. 8 are installed in the direction of the louver 210c in which they are installed. It can be moved by pulling and sliding.

The support bar 240 is installed eccentrically from the tilting axis of the louver 210 on one side of the louver 210.

The connection wire 250 connects the support bar 240 and the support bar 240 installed on another louver 210.

That is, the connection wire 250 corresponds to a configuration for rotating another louver 210b accordingly when one louver 210a is rotated.

The first opening / closing motor 260 is installed in the inner space of the third frame 130 and is formed extending from the tilting motor 220 connected to the louver 210 installed closest to the third frame 130. While winding or unwinding the chain, the tilting motor 220 is pulled in the direction of the third frame 130.

The second opening / closing motor 270 is installed in the inner space of the fourth frame 140 and extends from the tilting motor 220 connected to the louver 210 installed closest to the fourth frame 140. While winding or unwinding the chain, the tilting motor 220 is pulled in the direction of the fourth frame 140.

That is, if the first opening / closing motor 260 corresponds to a driving device for opening the loop, the second opening / closing motor 270 corresponds to a driving device for closing the loop.

9 is a diagram illustrating a schematic configuration of a roof awning system according to another embodiment of the present invention.

Referring to FIG. 9, the roof awning system 20 according to another embodiment of the present invention includes a roof frame part 100, a roof wing part 200, a support frame part 300, a rainwater sensor 400, and a stop It includes a device 500, an IP camera 600, a user terminal 700 and a loop control server 800.

Here, since the roof frame portion 100, the roof wing portion 200, and the support frame portion 300 are the same as the components in FIG. 1, description thereof will be omitted.

The rainwater sensor 400 detects the intensity and amount of rainwater.

The stop device 500 detects opening and closing of the roof wing 200.

The IP camera 600 photographs surrounding images.

The user terminal 700 installs a dedicated application for controlling the loop awning system, and is connected to the roof wing 200 through the network N to control opening and closing of the roof wing 200.

Here, the user terminal 700, a smart phone (Smart Phone), as well as a notebook (Notebook), a smart phone (Smart Phone), a desktop computer (PC), such as a tablet computer (Tablet PC) is widely used in the general public It is a broad concept that refers to various types of information communication devices and multimedia devices that support wired and wireless networks (N), such as mobile communication terminals.

The loop control server 800 is connected to the roof wing 200 or the user terminal 700 through a network N, and uses the weather public data provided by the Meteorological Agency (P) to control the roof wing 200. It reads whether it is opened or closed, and controls opening and closing of the roof wing 200.

Meanwhile, the network N is a transmission medium for transmitting and receiving data between the user terminal 100 and the reward providing server 200, and may include, for example, wireless communication, wired communication, optical ultrasound, or a combination thereof. Body Area Network (BAN), satellite communication, cellular communication, Bluetooth, Near Field Communication (NFC), Infrared Data Association standard (IrDA), Wireless Fidelity (WiFi), and Worldwide Interoperability for Microwave access (WiMAX) are included in the communication path. Examples of possible wireless communication, Ethernet, Digital Subscriber Line (DSL), Fiber to the Home (FTTH), and Plain Old Telephone Service (POTS) are examples of wired communication that may be included in a communication network. In addition, communication networks can traverse multiple network topologies and distances. For example, the communication network may include a direct connection, a personal area network (PAN), a local area network (LAN), a metropolitan area network (MAN), a wide area network (WAN), or any combination thereof. In addition, it may be made through a low power wide area network including LoRaWAN, NB-Fi, and RPMA. However, the network (N), the description of the communication network is not limited to the above-mentioned communication network, any latest data communication network may be applied.

In one embodiment, the loop control server 800 reads the altitude angle of the sun in real time using weather public data provided from the Korea Meteorological Agency, and the louver of the loop wing 200 according to the read altitude angle of the sun ( 210) to calculate the tilting angle of the louver 210 of the roof wing 200 to prevent sunlight from entering and entering the roof wing 200 against one side of the sun facing the sun, and opening and closing corresponding thereto The control signal may be generated and transmitted to the loop wing unit 200 through the network N.

In one embodiment, the loop control server 800 uses the image information received from the IP camera 600 to read the number of people located in the shade formed by the roof wing 200 and the location of the people, , The network (N) is generated by generating an opening / closing control signal for adjusting the opening / closing degree of the roof wing section 200 so that the shade formed by the roof wing section 200 can cover both the read number of people and the location of the corresponding people. It can be transmitted to the loop wing 200 through.

In one embodiment, the loop control server 800 reads the amount of snow accumulated on the upper side of the roof wing 200 in real time using weather public data provided from the Meteorological Agency, and the amount of snow accumulated in the roof wing 200 When it is read that the height is higher than a preset height, an opening / closing control signal for tilting the louver 210 of the roof wing 200 from 90 ° to 180 ° so that the snow accumulated on the roof wing 200 can fall downward. It can be generated and transmitted to the loop wing 200 through the network (N).

The loop awning system 20 according to another embodiment of the present invention having the above-described configuration may display real-time weather information received through the network N from the loop control server 800 through a screen display device or a voice output device. It may further include a notification unit (not shown in the drawing for convenience of description) to output using.

In one embodiment, the loop control server 800 uses a big data analysis based week signal derivation system (not shown in the drawings for convenience of description), which will be described below, for reading whether the roof wing 200 is opened or closed. You can.

Here, the system for deriving a week signal based on big data analysis includes: a collection management module for setting at least one collection criterion among a collection target data source module, a collection target keyword, and a collection target period; A data collection module that collects big data from the data source module and stores it in a database module according to data collection criteria set by the collection management module; A morpheme analysis module that analyzes the morpheme of the big data stored in the database module, classifies each morpheme, and generates morpheme analysis data; And a data analysis module that processes morpheme analysis data with a statistical analysis algorithm based on distributed parallel processing to calculate statistical values and outputs a weak signal according to the statistical values.

Here, the data analysis module, distributed file system for storing the morpheme analysis data; A data processing unit that provides a virtualized database interface to process morpheme analysis data existing in the distributed file system based on a structured query language (SQL); And executing a statistical analysis algorithm through the virtualization database interface provided by the data processing unit, from the morpheme analysis data, the number of appearances per year (instance frequencies), the number of simultaneous appearances between words and words by year, the frequency of appearances by year, and the year It may include a statistical analysis unit for calculating at least one or more of the processed values from the number of simultaneous occurrences between words and words.

Then, the statistical analysis unit, the statistical analysis unit may calculate the number of occurrences per word increase based on the number of occurrences (instance frequencies) by the year and the number of occurrences between words and words.

In addition, the statistical analysis unit divides the number of occurrences per year (instance frequencies) by the number of documents per year and normalizes the frequency of occurrence of the words per document per year to calculate the rate of increase in the frequency of occurrence of the standardized words for the words. You can.

In addition, the statistical analysis unit calculates the increase in the degree of centrality of connection by word using the matrix of the number of concurrent occurrences between words and words, and the increase in the frequency of occurrence of the standardized word and the increase in the degree of centralization of connection degree is higher than a certain part or Words that are less than a certain sub-portion can be derived as a week signal.

Meanwhile, the data collection module may collect big data including at least one unstructured data among image, video, voice, sensor, GPS, GIS, and M2M data.

That is, the loop control server 800, pedestrians who take a break in the shade formed by the present invention or temporarily avoid the rain or snow through the big signal analysis based week signal derivation system having the configuration as described above Collects and analyzes search terms, etc., searched through pages, etc., and uses the analyzed values calculated using big data to calculate whether or not to open or close the roof wing 200, and thus to generate the loop according to the present invention It is possible to provide an optimized shade or shelter for pedestrians on the lower side of the road.

10 is a view showing the support frame of FIG. 1.

Referring to FIG. 10, the support frame portion 300 is installed at each lower side of the roof frame portion 100 and peddled in a configuration for supporting the present invention.

In one embodiment, the support frame 300 may not only be provided with connecting brackets 310 and 320 for connecting between frames, but also may include an aluminum frame 330 made of aluminum in the inner space. . Here, the aluminum frame 330 may be applied to an aluminum pipe structure used for water / electricity / gas / drainage / sewage.

In addition, the support frame 300 may also include a floor bracket 340 for fastening to a floor surface formed of concrete or the like.

The above-described embodiments are for illustration only, and those skilled in the art to which the above-described embodiments belong can easily be modified into other specific forms without changing the technical idea or essential characteristics of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope to be protected through the present specification is indicated by the claims, which will be described later, rather than the detailed description, and should be interpreted to include all the changed or modified forms derived from the meaning and scope of the claims and their equivalent concepts. .

10, 20: roof awning system
100: roof frame
200: roof wing
300: support frame
400: rainwater sensor
500: stop device
600: IP camera
700: user terminal
800: loop control server

Claims (2)

A roof frame portion formed in a square shape;
A roof wing part connected to the roof frame part to form a loop, and opening and closing the inner space of the roof frame part while tilting and sliding; And
Included in the support frame portion is installed on each lower edge of the roof frame portion to support the roof frame portion,
The roof frame portion, the first frame is formed extending in the front-rear direction; A second frame spaced apart from the first frame in a left-right direction and extended in a front-rear direction; A third frame extending right and left between the front end of the first frame and the front end of the second frame; And a fourth frame that is spaced apart in the front-rear direction from the third frame and extends left and right between a rear end of the first frame and a rear end of the second frame.
The roof wing portion, a plurality of louvers (Louver) is formed on one side is connected to the first frame and the other side is connected to the second frame to form a blade constituting the loop; A plurality of tilting motors connected to one side of the louver and tilting the louver clockwise or counterclockwise so as to open or shield the inner space of the roof frame portion; A plurality of links consisting of a first bar and a second bar connected in a "X" form with a tilting axis extending from one of the tilting motors to one side of the louver as a central axis so as to tilt the louver; A plurality of support bars installed eccentrically from the tilting shaft of the louver at one side of the louver; A plurality of connecting wires connecting the support bar and a support bar installed in another louver; It is installed in the inner space of the third frame, while winding or unwinding a chain formed from a tilting motor connected to a louver installed closest to the third frame and pulling the tilting motor in the direction of the third frame A first open / close motor; And a chain extending from a tilting motor installed in an inner space of the fourth frame and extending from a tilting motor installed closest to the fourth frame while pulling or unwinding the corresponding tilting motor in the direction of the fourth frame. The note includes a second opening and closing motor;
The first bar of the link is connected to one end so as to be rotatable to the other end of the second bar of the other link, which is disposed nearby.
The second bar of the link is connected to one end so as to be rotatable to the other end of the first bar of the other link that is disposed nearby.
The link that is installed and connected to the louver installed closest to the third frame includes the first frame and the one end of the first bar and the second bar, respectively, as the first opening / closing motor pulls the tilting motor connected thereto. The other ends of the first bar and the second bar are also separated from each other along the wall surface of the first bar and the second bar. As each end portion of the first bar and the second bar of the link is opened in a direction away from each other, the other louvers are pulled in the direction of the louver in which they are installed and slidingly moved,
The louver includes: a wing body that opens and closes an inner space of the roof frame part while tilting in a clockwise or counterclockwise direction; A first bending wing bent to be rounded upward from the front end of the wing body; And a second bending wing that is bent to be rounded downward from the rear end of the wing body.
A rainwater sensor that detects the intensity and amount of rainwater; A stop device that detects opening and closing of the wing portion of the loop; An IP camera that shoots surrounding images; A user terminal that installs a dedicated application for controlling the roof awning system, and is connected to the roof wing through a network to control opening and closing of the roof wing; And a loop control server which is connected to the roof wing or the user terminal through a network, reads whether the roof wing is opened or closed using weather public data provided by the Korea Meteorological Agency, and controls opening and closing of the roof wing. Includes,
The loop control server reads the altitude angle of the sun in real time using weather public data provided from the Korea Meteorological Administration, and one side of the louver of the roof wing faces the sun according to the read altitude angle of the sun. After calculating the tilting angle of the louver of the loop wing portion for preventing the loop wing portion from talking and entering, the opening and closing control signal corresponding thereto is generated and transmitted to the loop wing portion through a network.
The loop control server reads the number of people located in the shade formed by the roof wing portion and the location of the people using the image information received from the IP camera, and reads the shade formed by the loop wing portion. Generates an opening and closing control signal for adjusting the degree of opening and closing of the roof wing portion so as to cover both the number of persons and the location of the corresponding people, and transmits it to the roof wing portion through a network,
The loop control server reads the amount of snow accumulated on the upper side of the roof wing in real time using weather public data provided by the Korea Meteorological Administration, and when it is read that the amount of snow accumulated in the roof wing is higher than a predetermined height, the loop wing Generates an opening and closing control signal for tilting the louver of the roof wing portion from 90 ° to 180 ° so that the snow accumulated in the part falls downward, and transmits it to the loop wing part through the network.
It further includes a notification unit for outputting real-time weather information received from the loop control server through a network using a screen display device or a voice output device.
The loop control server includes: a collection management module for setting at least one collection criterion among a collection target data source module, a collection target keyword, and a collection target period; A data collection module that collects big data from the data source module and stores it in a database module according to data collection criteria set by the collection management module; A morpheme analysis module that analyzes morphemes of the big data stored in the database module, classifies each morpheme, and generates morpheme analysis data; And a data analysis module that processes the morpheme analysis data with a statistical analysis algorithm based on distributed parallel processing to calculate statistical values and outputs a week signal according to the statistical values. By reading whether or not the loop wing is opened,
Roof awning system.

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