KR20120030183A - Blind control system being interlocked with natural light and control method thereof - Google Patents

Abstract

PURPOSE: A sunshade control system interlocked with natural lighting and a control method thereof are provided to automatically control natural lighting depending on the altitude and angle of sunlight. CONSTITUTION: A sunshade control system interlocked with natural lighting comprises a drive unit(20), a sensor unit(30), and a control unit. The drive unit powers a sunshade(10). The sensor unit outputs a sensing signal for controlling the sunshade by measuring solar radiation changes. The control unit controls the drive unit depending on solar heat conditions contained in the outputted sensing signal and the altitude and angle of sunlight.

Description

Shade control system with natural light and its control method {BLIND CONTROL SYSTEM BEING INTERLOCKED WITH NATURAL LIGHT AND CONTROL METHOD THEREOF}

The present invention relates to a natural light interlocking awning control system, and more specifically, the sunshade is automatically controlled to adjust the amount of solar radiation flowing into the room according to the azimuth and altitude of the sun, the effect on creating a pleasant indoor environment and energy saving The present invention relates to a natural light interlocking shade control system and a control method thereof.

As the use of curtain walls in buildings increases, the heating and cooling loads through the shells increase significantly. In particular, in consideration of visual openness in the office space, the glass use area in the outer cover is greatly increased, the indoor inflow of direct sunlight through the summer glass has a great influence on the cooling load. In addition, because solar radiation is introduced into the room through glass, the brightness is caused by excessive brightness difference in the indoor space. In most buildings, sunshades (for example, roll screens, blinds, verticals, etc.) are installed in the room. Blocking the influx of solar radiation.

In case of roll screen, there are manual type and electric type. The electric roll screen is installed for the convenience of user and when it is impossible to operate manually. The control method is individual control using remote controller, individual switch control, individual computer connected to roll screen of each floor area. Control of occupants through the hospital.

However, since the conventional electric roll screen control method is arbitrarily adjusted by the occupants by using a remote controller, a switch, a computer, etc., not only does not immediately respond to outdoor solar conditions, but also requires unnecessary time and effort to control the roll screen. There is discomfort.

In addition, when there is no occupant or even if there are occupants, there is a limitation that control is not performed in an optimal state.

The present invention has been made to solve the above problems, to provide a natural light interlocking shade control system and a control method that can automatically adjust the inflow and blocking of natural light according to the altitude and azimuth of sunlight. have.

In addition, the present invention is a natural light interlocking shade control system and control method that can automatically adjust the inflow and blocking of natural light in consideration of the altitude and azimuth of the sun by direction (east, west, south, north), season, time The purpose is to provide.

It is also an object of the present invention to provide a natural light interlocking shade control system and control method for automatically controlling the opening and closing height of the roll screen according to the weather by checking the change in insolation through the solar sensor.

The present invention also provides a natural light interlocking shade control system and its control method, which can improve productivity by automatically controlling unpleasant light (hyung-glare) that worsens the working environment of occupants, without any additional operation. have.

In addition, it is an object of the present invention to provide a natural light interlocking shade control system and a control method that can create the optimal comfort conditions in the interior of the building, and minimize the waste of energy.

In order to achieve the above object, the present invention provides a control system for automatically controlling an electric awning installed in a building, the drive unit for operating the awning, sensing to measure the change in solar radiation flowing into the building to control the awning A control unit for controlling the driving unit in response to a sensor unit for outputting a signal, solar conditions included in a sensing signal output from the sensor unit, and an altitude and azimuth angle of the sun calculated for each season, azimuth, and time of the building; There is provided a natural light interlocking shade control system.

In the present invention, the control unit may calculate and control the altitude and azimuth angle of the sun for each season, orientation, and time of the building to control by specifying a date-specific schedule corresponding to one year.

In the present invention, the control unit is a main server capable of controlling the entire, surface, floor, floor, area, and individual awning of the building, and transmits a control command by the main server to the drive unit and the control state of the drive unit to the main It may include a relay device for transmitting to the server.

In the present invention, the sensor unit may include a solar sensor for measuring one or more conditions selected from the group consisting of the sun's altitude, illuminance, direct solar radiation, scattering solar radiation, outdoor temperature.

In the present invention, the control system is connected via a network with a building management system that manages lighting, air conditioning, ventilation, and fire of the building, and the control unit controls the driving unit in response to management information transmitted from the building management system. can do.

In addition, the control method for achieving the object of the present invention as described above, the awning control method for automatically controlling the electric awning installed in the building, (a) the altitude of the sun by season, orientation, time of the building Calculating an azimuth angle and setting an initial value of the sunshade opening and closing; (b) measuring an amount of solar radiation flowing into the building and outputting a sensing signal to the controller; and (c) the sunshade corresponding to the initial value and the sensing signal. Comprising the step of calculating the height of, and (d) outputting a control signal for controlling the drive unit with the calculated height of the shade.

In the present invention, the step (a) may calculate the altitude and azimuth of the sun by season, by bearing, and by time of the building, and may set an initial value by specifying a schedule for each day corresponding to one year.

In the present invention, when the amount of insolation measured in the step (b) does not meet the reference value it can be controlled to expand the sunshade.

In the present invention, in the step (d), it is possible to control the entire awning, floor, surface, zone, and individual of the building.

In the present invention, the method may further include receiving management information through a network from a building management system that manages lighting, air conditioning, ventilation, and fire of the building, and may control the driving unit in response to the management information.

According to the present invention, by adjusting the height and azimuth of the sun according to the season, time, direction (east, west, south, north) sun and automatically adjusts the height of the awning, it is possible to adjust the awning to the optimal state without separate operation of the occupants It has an effect.

Therefore, it is possible not to waste time and effort of the occupants, and to concentrate on work, thereby greatly contributing to productivity improvement.

In addition, by blocking direct sunlight from entering the room and securing the maximum view in the work space, it is possible to prevent unpleasant light (hyeonhui) that worsens the working environment of the occupants and create a pleasant office environment.

In addition, it is possible to check the change in solar radiation flowing through the solar sensor to automatically control the roll screen according to the weather.

In addition, it is possible to control the entire, surface, floor, area, individual shade of the building, there is an effect that can be various operations.

In addition, there is an effect that can control the roll screen in conjunction with the building management system that manages the lighting, air conditioning, ventilation, fire of the building.

1 is a block diagram of a natural light interlocking shade control system according to an embodiment of the present invention,
2 is a flowchart illustrating a control method of a natural light interlocking shade control system according to an embodiment of the present invention;
3A to 3D show an application example of the present invention, which shows the expected elevation and azimuth angle of the sun according to seasons and times;
4A to 4C show an application example of the present invention, which shows the altitude of the anticipated sun by orientation.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and in the following description with reference to the accompanying drawings, the same or corresponding components are given the same reference numerals and redundant description thereof will be omitted. Shall be.

1 is a view schematically showing the configuration of the natural light interlocking shade control system according to an embodiment of the present invention.

The control system in this embodiment basically includes a sunshade 10 installed on the interior side of a building. The sunshade 10 is a component for controlling the inflow of sunlight and sunlight into the room and natural light. The sunshade according to the present embodiment may include a roll screen, a blind, a curtain, a louver, and the like, and a vertical blind and a Venetian. It may include a variety of devices, structures, facilities, etc. that can control, limit and block the insolation and sunshine inflow into the room, such as blinds, overhang (overhang).

In an embodiment of the present invention will be described taking an electric roll screen as the sunshade 10 as an example.

The control system for controlling the awning 10 of the present invention outputs a sensing signal to control the awning 10 by measuring the driving unit 20 for operating the awning 10 and the solar radiation change flowing into the building. The driving unit 20 corresponds to a solar condition included in a sensor unit 30 and a sensing signal output from the sensor unit 30, and an altitude and azimuth angle of the sun calculated for each season, azimuth, and time of the building. It includes a control unit for controlling, according to the operating height of the sunshade 10 is a system that can control the indoor environment of the building.

The sunshade 10 is coupled to the drive unit 20 and its operation is controlled by the control unit.

The mechanical configuration of the drive unit 20 may vary depending on the type of sunshade 10. For example, when the blinds are used as the shade 10, components such as a motor, a gear, etc., which can adjust the angle of inclination of the slats to control the light passing through the blinds, and move the entire blind up and down to shield the area of the blinds. Adjustable links, wires and other components may be used.

On the other hand, when using the roll screen proposed as an embodiment of the present invention as the sunshade 10, components such as motors, pulleys, rails for moving the roll screen can be used, the position of the sun by the latitude, longitude, etc. of the building The height of the roll screen can be controlled to block direct sunlight and ensure maximum view.

The sensor unit 30 measures the change in solar radiation flowing into the building, and is installed on the roof of the building to measure one or more conditions selected from the group consisting of sun altitude, illuminance, direct solar radiation, scattering solar radiation, and outdoor temperature. It may be made of a sensor.

In addition, the sensor unit 30 may be installed on the surface of the window to measure the illuminance of the sun, and transmits a sensing signal to the control unit through a separate interface (32).

The control unit may calculate and control the altitude and azimuth angle of the sun by season, azimuth, and time of the building to designate and control a date-specific schedule corresponding to one year. For example, depending on where the building is located, the sun's altitude can vary by orientation (east, west, south, north), and the sun's altitude and azimuth will change at the same time, depending on the season. As such, by calculating the altitude and azimuth of the sun by season, by bearing, and by time, it is possible to designate a control schedule for each day corresponding to one year.

Here, the height of the sunshade 10 is calculated in response to a condition such as the amount of insolation measured through the sensor unit 30, and the drive unit 20 is controlled.

The control unit transmits a main server 110 for central control, a control command by the main server 110 to the driving unit 20, and transmits a control state of the driving unit 20 to the main server 110. It includes a relay device 120.

The main server 110 sends a control command to the drive unit 20 to control the entire shade 10 of the building. That is, the function of controlling the driving unit 20 in response to the solar condition included in the sensing signal output from the sensor unit 30 and the altitude and azimuth of the sun calculated for each season, azimuth, and time of the building To perform.

At this time, the main server 110 may not only send a control command to collectively control the entire awning 10 of the building, but also by the east, west, south, north of the building, the floor, floor, area, Send control command to control individual shades.

In addition, by designating a special day (holiday, etc.) to meet the user's conditions, it is possible to control the drive unit 20, to display the state of the sunshade 10 and to store the usage record.

In this embodiment, the control system is connected to the building management system 112 that manages the lighting, air conditioning, ventilation, and fire of the building through a network. The building management system 112 determines the lighting, air conditioning, ventilation, fire preparedness of the building by a manager's operation or as preset, and sets the required room temperature and / or humidity.

Therefore, the main server 110 may control the drive unit 20 in response to the management information transmitted from the building management system 112.

On the other hand, in the present embodiment, it is preferable that the user (resident or manager of the building) is configured to be accessible to the user from the user terminal 114 through the network to use the shade control system in real time.

In addition, the shade control system of the present invention is to give priority to automatically control the shade 10 of the building through the control unit, it can be configured to enable user control. To this end, in an embodiment of the present invention, the user to control the floor control switch 130 and the individual or group-specific shade 10 to output a control signal to collectively control the shade 10 of each floor or a designated area. RF control unit 140 for outputting a radio control signal corresponding to the operation of the signal receiving unit (not shown) installed in the drive unit 20 to receive the radio control signal is further included.

Hereinafter, a method of controlling the shade in the shade control system described above will be described in detail.

2 is a flowchart illustrating a control method of a natural light interlocking shade control system according to an embodiment of the present invention.

First, an initial value of the sunshade opening and closing is set by calculating the altitude and azimuth angle of the sun for each season, azimuth, and time of the building (S100).

Here, the initial value setting item may include a season, the orientation (east, west, south, north) of the surface on which the awning is installed, the time, the location of the building (latitude and longitude), the height of the window, and the like.

Thereafter, the control time is checked (S110), and if the control time is checked (S120).

When the sunrise is confirmed, the solar radiation is measured by the sensor unit 30 (S130).

It is determined whether the measured solar radiation exceeds the reference value (S140).

When the solar radiation exceeds the reference value, the control unit to automatically control the shade 10.

On the other hand, when the amount of insolation measured is less than the reference value, because the weather is cloudy, the sunshade 10 is fully developed (S200).

In order to automatically control the shade 10 in the control unit, the altitude of the sun is measured through the sensor unit 30 (S150).

The height of the sunshade 10 is calculated using the altitude of the sun measured by the sensor unit 30 and the set initial value (S160).

In order to control the drive unit 20 to the calculated height of the shade 10, first determine the state of the shade 10 (S170).

If the state of the current awning 10 is open than the calculated height of the awning 10 is closed (S180), if the state of the current awning 10 is closed than the height of the calculated awning 10 is opened (S190). ).

As such, when the height of the shade 10 is controlled to the calculated height of the shade 10, the flow returns to step 110 (S110).

If the sunrise is not confirmed in such a state, since it is a sunset, it is determined whether or not the instruction time to close the sunshade 10 (S210).

When it is confirmed that the instruction time has been closed, the shade is closed (S220).

When it is confirmed that the instruction time has not been reached, the sunshade is opened for a night view (S230).

In the present embodiment, in order to secure the view at night, all the doors are opened until the instruction time and all the doors are closed after the instruction time.

Hereinafter, in order to help the understanding of the present invention, the application of the shade control system according to the present invention will be described with reference to the accompanying drawings.

Figures 3a to 3d shows an application example of the present invention, a view showing the altitude and azimuth angle of the expected sun by season, hour, and Figures 4a to 4c shows an application example of the present invention, the expected altitude of the sun by orientation It is a figure which shows.

Figure 3a shows the azimuth angle of the sun expected in the spring, showing the azimuth angle of the spring sun of the building presented in the application example by time zone. In the application example of the present invention, the azimuth angle of the sun is 113 degrees 15 minutes and the altitude is 27 degrees 02 minutes at AM 09:00 in spring.

Later, at 13:00 PM, the azimuth is 188 degrees and 19 minutes and the altitude is 52 degrees and 07 minutes.

Later, at 17:00 PM, the azimuth is 254 degrees and 14 minutes, and the altitude is 19 degrees and 30 minutes.

On the other hand, Figure 3b shows the azimuth angle of the sun expected in the summer of the same building as in Figure 3a, the azimuth angle of the sun is 91 degrees 21 minutes, the altitude is 42 degrees 09 minutes at AM 09:00 during summer. At 13:00 PM, the azimuth is 203 degrees 27 minutes and the altitude is 74 degrees 49 minutes.

At 17:00 PM, the azimuth is 276 degrees 16 minutes and altitude is 32 degrees 09 minutes.

Figure 3c shows the azimuth angle of the sun expected in the fall, the azimuth angle of the sun is 115 degrees 58 minutes, altitude 29 degrees 53 minutes at AM 09:00 during autumn. At 13:00 PM the azimuth is 194 degrees and 18 minutes and the altitude is 51 degrees and 40 minutes. At 17:00 PM, the azimuth is 256 degrees and 44 minutes, and the altitude is 16 degrees and 39 minutes.

FIG. 3d illustrates the azimuth angle of the sun, which is expected in winter, at 9:00 AM in winter, the azimuth angle of the sun is 132 degrees 02 minutes, and the altitude is 11 degrees 35 minutes. At 13:00 PM, the azimuth is 187 degrees 52 minutes and altitude is 28 degrees 36 minutes. At 17:00 PM, the azimuth is 238 degrees and 01 minutes, and the altitude is 02 degrees and 03 minutes.

As described above, the azimuth and altitude of the sun vary according to the seasons represented by spring, summer, autumn, and winter, and the azimuth and altitude of the sun vary according to time zones. Thus, the sunshade is controlled by setting the initial value.

On the other hand, looking at the altitude of the sun according to the orientation, Figure 4a is a diagram showing the light flows into the east side of the building at 9 am by season. On the east side of the building, the sun's elevation is 27 degrees and 02 minutes at 9 am equinox, the sun's altitude is 42 degrees and 29 minutes when it's not, and the sun's altitude is 29 degrees and 53 minutes at autumn and 11 degrees 35 degrees. Minutes.

On the other hand, Figure 4b shows the expected influx of light on the west side of the building at 5 pm, the sun's altitude at 19 degrees 30 minutes during the spring equinox, the sun's altitude at 32 degrees 09 minutes at the spring equinox, and the elevation of the sun at the autumn equinox. Is 16 degrees 39 minutes, and the sun is 02 degrees 03 minutes.

In addition, at 1 pm on the south side of the building, as shown in FIG. Minutes, the sun is 28 degrees and 36 minutes at winter solstice.

As such, since the altitude of the sun for each season can be estimated according to the orientation of the building, it is possible to control the opening and closing height of the sunshade.

In the awning control method of the present invention by calculating the altitude and azimuth angle of the sun according to the building's orientation, seasonal, hourly sun and programmed to the controller, it is possible to automatically open and close the shade.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

10: shade 20: drive unit
30: sensor unit 110: main server
120: relay device 130: floor control switch
140: RF remote control

Claims (10)

As a control system for automatically controlling the electric shade installed in the building,
A drive unit for operating the sunshade;
A sensor unit configured to output a sensing signal to control the sunshade by measuring a change in solar radiation flowing into a building; And
A control unit controlling the driving unit in response to the solar condition included in the sensing signal output from the sensor unit and the altitude and azimuth angle of the sun calculated for each season, azimuth, and time of the building;
Natural light interlocking shade control system comprising a. The method of claim 1,
The control unit calculates the sun's altitude and azimuth angle by season, azimuth, and time of the building to control by specifying a schedule for each day corresponding to one year. The method according to claim 1 or 2,
The control unit,
Main server that can control the whole building, surface, floor, area, and individual awnings,
And a relay device which transmits a control command by the main server to the driving unit, and transmits a control state of the driving unit to the main server. The method of claim 1,
The sensor unit is a natural light interlocking shade control system comprising a sun sensor for measuring one or more conditions selected from the group consisting of the sun's altitude, illuminance, direct solar radiation, scattering solar radiation, outdoor temperature. The method of claim 1,
The control system is connected through a network with the building management system that manages the lighting, air conditioning, ventilation, and fire of the building,
The control unit is a natural light interlocking shade control system, characterized in that for controlling the drive in response to the management information transmitted from the building management system. A shade control method for automatically controlling the electric shade installed in the building,
(a) calculating the sun's altitude and azimuth angle for each season, azimuth, and time of the building to set initial values of the sunshade opening and closing;
(b) measuring the amount of solar radiation flowing into the building and outputting a sensing signal to the controller;
(c) calculating the height of the shade according to the initial value and the sensing signal; And
and (d) outputting a control signal for controlling the driving unit to the calculated height of the shade. The method of claim 6,
Step (a) is the natural light interlocking shade control method characterized in that by setting the initial value by specifying a schedule for each day corresponding to the year by calculating the altitude and azimuth of the sun by the season, the bearing, the time of the building . The method of claim 6,
When the amount of insolation measured in the step (b) does not meet the reference value, the natural light interlocking shade control method characterized in that the development of all. The method of claim 6,
In the step (d), the natural light interlocking shade control method characterized in that the entire awning, floor, surface, area, individual control of the building is possible. The method of claim 6,
Receiving management information through a network from the building management system for managing the lighting, air conditioning, ventilation, fire of the building,
Natural light interlocking shade control method characterized in that for controlling the drive in response to the management information.

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