JPH0317381A - Insolation-control blind device - Google Patents

Abstract

PURPOSE:To reduce the size of an insolation-control blind device by a method in which the irradiating angle of the sunlight is obtained from the height and bearing of the sun to a window as well as the bearing of the window and the optimum angle of slat is calculated to adjust the slats of a blind. CONSTITUTION:The latitude and longitude of a building are read from the latitude and longitude setter of a centralized control unit 25, and the dates are read from a calender timer 28 to calculate the height and bearing of the sun. The signals of the latitude and height of the sun which are sent out from the transmission interface 33 of the unit 25 are sent through a transmission line 26 to an insolation control unit 24 where the height and bearing of the sun are read. Also, the direction of window set in a window bearing setter 39 is read to calculate the direction of the sun on the basis of the vertical face of the window. The optimum angle of slats is calculated from the direction based on the vertical face of the window and the calculated height. While the angle by an angle sensor 23 is fed back in such a way as to obtain an optimum angle of slats, the motor 22 is turned.

Description

Detailed Description of the Invention <Industrial Application Field> The present invention is a solar radiation control blind device that obtains an optimal blind effect by adjusting the slat angle of the blind. This invention relates to a solar radiation control blind device that performs.

<Prior art> Fig. 8 and Fig. 9 show a conventional solar radiation control blind device. The rotation angle detector 4 is a solar radiation control unit that automatically determines the optimal slat angle and adjusts the slats of the blind to that angle.
As shown in the block diagram shown in FIG. 9, a latitude and longitude setting step 5 sets the latitude and longitude of the building where the blind is installed, and a window orientation setting means 6 sets the orientation of the window where the blind is installed. A calendar timer 7 that counts the date and time, a driver circuit 8 for the motor 2, a 1,000-level display 9 that displays the setting values, date and time, slat angle, etc. by each of the above-mentioned setting means, and a drive for the 1,000-level display 9. circuit 10
and a microcomputer 18 consisting of an operation switch 11 for setting the date and time, an interface 12, an output circuit 13, an input circuit 14, a memory 15, a CPU 16, an A/D converter 17, etc. .

The solar radiation control unit 4 configured in this manner uses a microcomputer 18 to monitor the altitude of the sun from moment to moment based on the latitude data, longitude data, date data, and time data inputted from the latitude and longitude setting means 5 and the calendar timer 7. and calculate the direction of the sun relative to the center of the south.

Next, the azimuth of the sun based on the window surface is calculated from the azimuth data of the window based on the south center inputted by the window azimuth setting means 6, and the azimuth of the sun based on the window surface and the azimuth of the sun calculated as above are calculated. Based on the altitude of the sun, find the optimal slat angle with the slats opened to the maximum within a range where direct sunlight does not enter the room, and then use the motor 2 and slat rotation angle detector 3 to adjust the slats to the above angle. feedback control.

It should be noted that the microcomputer 18 repeats the above operation at regular time intervals in accordance with the program stored in the memory 15 to execute solar radiation control for the blinds.

<Problems to be Solved by the Invention> Since the conventional solar radiation control blind device is configured as described above, when a plurality of blind devices are installed in one building, it is necessary to individually set the building's latitude and longitude setting means and calendar. It is necessary to provide a timer, display means, operation switch for setting the calendar timer, etc., and also requires a large capacity memory to store the program for calculating the altitude and direction of the sun from moment to moment. The problem is that the control unit becomes large, and when it is attached to a window, it spoils the appearance and increases the cost. In addition, settings such as latitude and longitude, date, and time must be set individually.
It was extremely inconvenient to operate.

The present invention was developed to solve the above-mentioned problems, and aims to make a solar radiation control unit more compact and to obtain a solar radiation control blinding device that is inexpensive and easy to operate. .

<Means for Solving the Problems> In order to solve the above problems, a solar radiation control blind device according to the present invention is a solar radiation control blind device that controls solar radiation of a plurality of blinds installed in one building.
A latitude and longitude setting means for setting the latitude and longitude of a building, a date and time counting means for counting the date and time, a date and time counting means for counting these latitudes and longitudes and the date and time, and a momentary altitude of the sun from these latitudes and longitudes and the date and time. window orientation setting means for setting the orientation of the window in which the blind is installed; , a receiving means for receiving the solar altitude and azimuth signal from the output means, and a slat angle calculating means for calculating the optimal slat angle by determining the irradiation angle of the sun with respect to the window from the window azimuth and the sun's altitude and azimuth. and an adjusting means for adjusting the slat angle of the blind to the slat angle, and a plurality of solar radiation control units installed in each window are connected by a transmission line.

<Operation> Since the solar radiation control blind device according to the present invention is configured as described above, the altitude and direction of the sun necessary for solar radiation control are calculated from the latitude and longitude of the building and date and time data in the central control unit. This is transmitted to multiple solar radiation control units installed in each window blind, which determines the sun's irradiation angle with respect to the window from the window's direction and the sun's altitude and direction, and calculates the optimal slat angle. Solar radiation can be controlled by adjusting the slat angle of the blind. Therefore, latitude and longitude setting means, date and time counting means, for calculating the altitude and direction of the sun,
It is sufficient to centrally provide the calculation means in one place, and there is no need to provide means for individually calculating the altitude and direction of the sun in the solar radiation control unit installed in each window blind.

<Example> An example of the present invention will be described below based on FIGS. 1 to 6.

In Figure 1. 21 is a blind body, 22 is a motor for adjusting the slat angle of the blind, 23 is a slat angle detector, 24 is a solar radiation control unit that controls the slat angle of the blind via the motor 22, 25
The solar radiation control unit 24 calculates the altitude and direction of the sun.
It is a central control unit that transmits data to the sun and is connected via a transmission line 26 to a plurality of solar radiation control units 24 provided in the blinds of each window.

As shown in the block diagram of FIG. 2, the central control unit 25 includes latitude and longitude setting means 27 for setting the latitude and longitude of the building.
and a calendar timer 28 that automatically counts the date and time.
, an operation switch 29 for setting the date and time on the calendar timer 28, a 1,000-stage display 30 for displaying calendar timer setting values, etc., and a driver circuit 31 for the 1,000-stage display 30.
A microcomputer 32 reads the latitude and longitude from the latitude and longitude setting 1,000 steps 27 and the date and time from the calendar timer 28 to calculate the sun's altitude and azimuth from moment to moment, and a transmission line that transmits the calculated sun's altitude and azimuth. The microcomputer 32 is connected to an interface 34, an output circuit 35, an input circuit 36, and a transmission interface 33 that sends data to 26. It is controlled by J37, CPU38, etc.

Further, as shown in the block diagram of FIG. 3, the solar radiation control unit 24 includes a window orientation setting means 39 for setting the orientation of the window, a transmission interface 40 for receiving transmission signals from the transmission line 26, and a driver for the motor 22. The circuit 41 and the window orientation and transmission interface 40 from the window orientation setting means 39
The sun's altitude and azimuth received are read, the sun's irradiation angle with respect to the window is determined, and the optimal slat angle is calculated. Based on this and the feedback signal from the angle detector 23, the motor 22 is driven and a microcomputer 42 that drives the slats and controls the slats to the above-mentioned optimum slat angle. I'm selling it.

In the solar radiation control blind device configured as described above, the operation of the central control unit 25 will first be explained based on the operation flowchart shown in FIG. After counting the interval time, the latitude and longitude of the building are read from the latitude and longitude setting means 27, and then the date and time are read from the calendar timer 28, and from these, calculations of sun declination, average time difference, and hour angle are performed. The altitude and azimuth of the sun are calculated sequentially according to the following formulas.

δ==CO-CI XCOS(W+Kl)-C2
Xcos(2W+K2)-C:l xcos
(3W+K3)△T = -C4 + C5 X
COS(W+K4)-CaXCOS(2WX K
5) - C-t・K
, XY, Ko~K, ... constant, t=isx (T
m+ΔT-12)+(L-1:15),h
= sin-'(sinφ-sinδ+COStpII
cos δ●cost) A = cos''' [(sin
h●sin ψ-sin δ)/COShI1 cos ψ1 However, t...Hour angle, Tm...Standard time, h...Solar altitude, L...Longitude, A...Solar direction, ψ...Latitude.

The values of the sun's altitude h and azimuth A obtained by the above calculation are converted into binary values and sent to the transmission interface 33 as bit signals. Afterwards, repeat Mr. Machimuka's actions to count up the next interval time.

On the other hand, the solar altitude and azimuth signals sent from the transmission interface 33 are sent via the transmission line 26,
It is received by the transmission interface 40 of each solar radiation control unit 24. In each solar radiation control unit 24, according to the program recorded in the memory 43 of the microcomputer 42, as shown in the operation flowchart shown in FIG.
First, the transmission interface 40 reads the received altitude and direction of the sun. Next, the window orientation set in the window orientation setting means 39 is read, and the solar orientation with the window vertical plane as a reference is calculated from this and the altitude and orientation of the sun.

Then, based on the solar direction based on the window vertical plane and the calculated solar altitude, the optimal slat angle is determined according to the relationship shown in Figures 6 and 7, that is, within the range where direct sunlight does not enter the room. Find the angle at which the slats open to the maximum. The slats of the blind are controlled to the optimum slat angle obtained in this way by rotating the motor 22 forward or reverse while taking angle feedback using the angle detector 23. Below, the central control unit 25
The same operation is repeated every time a signal is transmitted from the slat angle, changing the slat angle over time. Effects of the Invention> As is clear from the above explanation, according to the solar radiation control blind device according to the present invention, one centralized control unit calculates the altitude and direction of the sun, which changes from moment to moment, Since the information is transmitted to multiple solar radiation control units installed at It is possible to improve the appearance and reduce costs. In addition, you can set the latitude and longitude of the building, modify the date and time settings, etc.
It is possible to greatly improve operability because only one location is required. can be controlled.

[Brief explanation of the drawing]

FIG. 1 is an overall configuration diagram of a solar radiation control blind device according to the present invention, FIG. 2 is a block diagram of a central control unit, and FIG.
A block diagram of the solar radiation control unit, Figure 4 is an operation flowchart of the central control unit, Figure 5 is an operation flowchart of the solar radiation control unit, Figures 6 and 7 are the height and height of the sun with reference to the window surface. A relationship diagram for determining the optimum slat angle from the orientation, FIG. 8 is a diagram showing the structure of a conventional solar radiation control blind device, and FIG. 9 is a block diagram of the solar radiation control unit. In addition, in the figure, 21 is the blind body, 22 is the motor, and 23
is an angle detector. 24 is a solar radiation control unit. 25 is a central control unit, 26 is a transmission line, 27 is latitude/longitude setting means, and 28 is a calendar timer. 29 is an operation switch, 3
0 is a display means, 31 is a driver circuit. 32 is a microcomputer. 33 is a transmission interface, 34 is an interface, 35 is an output circuit, 36 is an input circuit, 37
is a memory, 38 is a CPU, 39 is a window direction setting means,
40 is a transmission interface, 41 is a motor driver circuit, 42 is a microcomputer, 43 is a memory,
44 is an input circuit, 45 is an output circuit, 46 is an A/D converter, and 47 is a CPU. Figure 4 Figure 5 Figure 7 Country 3 Figure 6

Claims (1)

[Scope of Claims] A solar radiation control blind device that controls solar radiation of a plurality of blinds installed in one building, comprising: latitude and longitude setting means for setting the latitude and longitude of the building; date and time counting means for counting the date and time; For one centrally controlled unit consisting of an altitude and azimuth calculation means that calculates the sun's altitude and azimuth moment by moment from these latitudes and longitudes and date and time, and an output means that sends out the solar altitude and azimuth signals,
window orientation setting means for setting the orientation of the window in which the blind is installed; receiving means for receiving the solar altitude and orientation signals from the output means; A plurality of solar radiation control units installed in each window are connected by a transmission line, consisting of a slat angle calculation means for determining the irradiation angle and calculating the optimal slat angle, and an adjustment means for adjusting the slats of the blind to this slat angle. A solar radiation control blind device characterized by: