KR100892298B1 - Power saving illumination system and controlation method for the same - Google Patents

Abstract

A power-saving lighting system and a method for controlling the same are provided to perform an optimal illuminance in a whole indoor space by controlling brightness of a plurality of lighting units according to ambient light. A sensor type lighting unit(100) comprises a firs light source, an illuminance sensor, an illuminance sensor input part, a main control part, a current control part, and a communication part. The sensor type lighting unit provides an optimal illuminance by controlling brightness of the first light source. The illuminance sensor input part transmits an illuminance value measured by the illuminance sensor to the main control part. The main control part generates a control signal for increasing or decreasing a current provided to the first light source according to the illuminance value received from the illuminance sensor input part. The communication part transmits the illuminance value measured by the illuminance sensor to an adjacent non-sensor type lighting unit. The non-sensor type lighting unit(200) includes a second light source, a communication part, a main control part, and a current control part. The non-sensor type lighting unit provides an optimal illuminance by controlling brightness of the second light source.

Description

Power-saving lighting system and its control method {POWER SAVING ILLUMINATION SYSTEM AND CONTROLATION METHOD FOR THE SAME}

The present invention relates to a lighting system, and in particular, a plurality of lights distributed in the indoor space is controlled to the appropriate brightness according to the ambient illumination to provide optimal illumination throughout the interior space and at the same time prevent unnecessary power consumption due to excessive lighting use. The present invention relates to a power saving lighting system and a control method thereof.

In the case of the interior, there is a window space with enough sunlight and an interior space that requires light irradiation because it is dark even during the day.

Even in the same indoor space, the required amount of light is different, but the current lighting method is a method of irradiating light with a single brightness over the entire space. On the contrary, if the brightness of the light is adjusted in consideration of the illumination of the inner space, excessive lighting in the window space not only causes the user to feel eye fatigue, but also causes unnecessary power consumption.

The present invention has been proposed to solve the above-mentioned problems of the prior art, and a plurality of lights distributed in the indoor space are controlled to an appropriate brightness according to the ambient illumination to provide optimal illumination throughout the interior space and at the same time use excessive lighting. It is an object of the present invention to provide a power saving lighting system and a control method thereof to prevent unnecessary power consumption.

According to an aspect of the present invention, there is provided an illuminance sensor for measuring an illuminance of a first light source and a surrounding, and the brightness of the first light source is adjusted so that an illuminance value measured by the illuminance sensor reaches an optimum value. The sensor-type lighting units and a second light source, and control the illumination space from the adjacent sensor-type lighting unit is installed distributed with the sensor-type lighting units in an indoor space that requires lighting, the received illuminance value is Provided is a power saving lighting system comprising unsensored lighting units that adjust the brightness of the second light source to reach an optimum value.

According to the present invention, since the plurality of lighting units distributed in the indoor space are controlled to the appropriate brightness according to the ambient illumination, not only the optimum illumination is provided for the entire indoor space, but also the inconvenience caused by excessive lighting usage and unnecessary power consumption are prevented. do.

The objects, features and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings. In addition, terms used in the present invention have been described by selecting general terms that are widely used at present. Of course, if the term is not commonly used, its meaning is described in detail in the corresponding parts.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described.

1 is a view showing an embodiment of a power saving lighting system according to the present invention, Figure 2 is a block diagram showing the configuration of the sensor-type lighting unit, Figure 3 is a block diagram showing the configuration of the non-sensor type lighting unit.

As shown in FIG. 1, the energy-saving lighting system according to the present invention includes sensor-type lighting units 100 and non-sensor-type lighting units 200 and a user, which are distributed and installed in an indoor space 10 requiring lighting. The control unit 300 and the display unit 400 are included.

As shown in FIG. 2, the sensor-type lighting unit 100 includes a light source 101, a main control unit 102, a current control unit 103, a power supply unit 104, a communication unit 105, and a user input / output unit 106. And an illumination sensor input unit 107.

An LED lamp may be used as the light source 101.

The illuminance sensor input unit 107 reads an illuminance value of an illuminance sensor (not shown) for measuring the illuminance of the surroundings.

The main controller 102 is a conventional micro controller unit (MCU). The main controller 102 determines whether the surrounding brightness is excessive or insufficient according to the illuminance value from the illuminance sensor input unit 107. It outputs to the control part 103. Specifically, the main controller 102 determines that the illumination value from the illumination sensor input unit 107 is excessively bright and outputs a negative control signal to the current controller 103. When the illuminance value from the illuminance sensor input unit 107 is smaller than the optimum value, it is determined to be dark, and a positive control signal is output to the current control unit 103.

The optimal value is an illuminance value that is determined to be most suitable for the indoor space 10 requiring illumination, and may be a different value depending on the purpose of use of the indoor space 10. In addition, the optimum value may be a value within a certain range, or may be a specific value having no range.

The main controller 102 receives a current value from the current controller 103 in response to the control signal, calculates power consumption based on the counted time and the received current value after counting the time since the current value is received. do.

The main control unit 102 includes a dip switch for indicating that the sensor type lighting unit. The dip switch is set to a value indicating a sensor type, for example '0'.

The current controller 103 adjusts the brightness of the light source 101 by increasing or decreasing the current value supplied to the light source 101 by a predetermined magnitude Δ according to the control signal from the main controller 102. Specifically, when the negative control signal is received from the main controller 102, the current controller 103 reduces the current value supplied to the light source 101 by a predetermined magnitude Δ to decrease the brightness of the light source 101. Decrease. When the positive control signal is received from the main controller 102, the current value supplied to the light source 101 is increased by a predetermined magnitude Δ to increase the brightness of the light source 101.

The current controller 103 transmits the current value supplied to the light source 101 to the main controller 102.

The power supply 104 may be configured integrally with the sensor-type lighting unit 100, as shown in the figure, may be configured separately.

When the power supply unit 104 is integrally formed, the power supply unit 104 converts commercial AC power supplied through the power lead wire into DC power required for the sensor type lighting unit 100. The power supply 104 generates a voltage required by elements driven by a DC voltage among the elements of the sensor-type lighting unit 100 and supplies the generated voltage to the corresponding element. In the illustrated example, only a path for supplying power input through the power supply unit 104 to the main control unit 102 is shown to avoid the complexity of the drawing. However, the power input through the power supply unit 104 is the remaining DC driving element, for example. For example, it is also supplied to the light source 101, the current control part 103, the communication part 105, etc.

On the other hand, when configured as a separate type, the power supply unit 104 is installed outside the sensor-type lighting unit 100 to supply DC power to the lighting units (100, 200). In this case, power may be supplied to the plurality of lighting units 100 and 200 from one power source 104. In addition, since the power supply unit 104 is removed from the lighting units 100 and 200, the size of the lighting units 100 and 200 is reduced.

The communication unit 105 transmits the illuminance value from the main control unit 102 to the non-sensor type lighting unit 200.

As shown in FIG. 3, the non-sensor type lighting unit 200 does not have an illuminance sensor input unit 107, unlike the sensor type lighting unit 100, and transmits an illuminance value through the communication unit 205. 100). In addition, the dip switch of the main controller 202 is set to a value indicating non-sensor type, for example, '1'.

Since the configuration of the other non-sensor type lighting unit 200 is the same as that of the sensor type lighting unit 100, the detailed configuration and operation of the non-sensor type lighting unit 200 are described in the above-described sensor type lighting unit 100. See.

The user control unit 300 includes a system mode selection key 301 for selecting any one of an automatic mode and a manual mode, an illumination unit selection key 302 for selecting a lighting unit to be controlled in the manual mode, and a manual mode. It includes a brightness selection key 303 for adjusting the brightness of the selected lighting unit, and outputs a signal corresponding to the key operation to the lighting unit (100, 200).

The system mode selection key 301 has an on / off key applied thereto. When the system mode selection key 301 is on, the system mode is in the automatic mode state.

The lighting unit selection key 302 has a numeric key applied thereto. Each lighting unit is assigned a unique identification number. The lighting unit is selected by pressing a numeric key corresponding to the identification number of the lighting unit to be selected.

The brightness selection key 303 has an up key 303A / down key 303B applied thereto. Up key 303A is used to increase the brightness of the selected lighting unit and down key 303B is used to lower the brightness of the selected lighting unit.

 The user control unit 300 is connected to the lighting units 100 and 200 by wire or wirelessly. When connected wirelessly, it is possible to control the lighting unit (100, 200) from a remote location.

The display unit 400 visually displays a message containing contents of a system mode setting state, a system error, etc. according to signals from the lighting units 100 and 200. As the display unit 400, for example, seven segments may be used.

On the other hand, the lighting unit (100, 200) receives a signal according to the key operation from the user control unit 300, the user to send a signal containing the contents of the system mode setting state and system error occurrence, etc. to the display unit 400 The apparatus further includes input / output units 106 and 206.

The user input / output units 106 and 206 include dip switches indicating a system mode setting state. The dip switch value indicating the system mode setting state is set by a signal according to the operation of the system mode selection key 301 of the user control unit 300.

The user input / output units 106 and 206 include a dip switch displaying a magnetic identification number, and receive an identification number according to an operation of the lighting unit selection key 302 of the user control unit 300 in the manual mode and corresponding identification number. Receives a signal according to the operation of the brightness selection key 303 of the user control unit 300 in the case of matching the identification number, and transmits the received signal to the main control unit (102, 201) to the light source (101, 201) Let the brightness of be controlled.

The automatic control method of the power saving type lighting system according to the present invention is as follows.

4 to 6 are flowcharts illustrating an automatic control operation of a power saving type lighting system according to the present invention.

As shown in FIGS. 4 to 6, when the automatic mode is selected through the operation of the system mode selection key 301 of the user control unit 300, and a signal corresponding thereto is input to the user input / output units 106 and 206, the lighting is performed. Initialize the unit system (S101, S102).

Then, the dip switch values of the main controllers 102 and 202 are read to determine whether the system to which the main controllers 102 and 202 belong is a sensor type lighting unit or a non-sensor type lighting unit (S103 and S104). For example, when the dip switch value of the main controllers 102 and 202 is '0', it is determined as a sensor type lighting unit, and when it is '1', it is determined as a non-sensor type lighting unit.

As a result of the determination in step S104, when it is confirmed that the sensor-type lighting unit is determined whether there is an error in the operation of the sensor-type lighting unit 100 (S201, S202).

This is because, while changing the current value provided to the light source 101 in steps of 50%, 60%, 70%, 80%, 90%, and 100% of the maximum current value, whether the illumination intensity change by the system control occurs in each step. You can judge whether or not.

At this time, if the change in illuminance does not occur, it is determined that an error has occurred and transmits an error message signal to the display unit 400 (S203).

On the other hand, when a change in illuminance occurs, it is determined that there is no error and leads to the illuminance value measured by the illuminance sensor (S204).

Then, the read illuminance value is sent to the non-sensor type lighting unit 200 through the communication unit 105 (S205).

Next, it is determined whether the read illuminance value is larger than the optimum value (S206).

As a result of the determination in step S206, when it is determined that the led illuminance value is larger than the optimum value, the current I provided to the light source 101 is decreased by a predetermined magnitude Δ to decrease the brightness of the light source 101, and then S204. Returning to the step (S207), if it is confirmed that the readout illuminance value is not greater than (less than or equal to) the optimum value, it is determined whether the readout illuminance value is less than the optimum value (S208).

As a result of the determination in step S208, when it is confirmed that the read illuminance value is smaller than the optimum value, the current I provided to the light source 101 is increased by a predetermined magnitude Δ to increase the brightness of the light source 101, and then step S204. (S209), when it is confirmed that the read illuminance value corresponds to the optimum value, the current I supplied to the light source 101 is maintained as it is, and the flow returns to step S204 without changing the brightness of the light source 101. (S210).

On the other hand, when the determination result of the step S103, S104, if the non-sensor type is confirmed, waits for the illuminance value from the sensor-type illumination unit 100 and receives the illuminance value from the sensor-type illumination unit 100 (S301, S302), the reception It is determined whether the calculated illuminance value is larger than the optimum value (S303).

As a result of the determination in step S303, when it is determined that the received illuminance value is larger than the optimum value, the current I provided to the light source 201 is reduced by a predetermined magnitude Δ to decrease the brightness of the light source 201, and then step S301. If it is determined that the received illuminance value is not greater than the optimal value (smaller or the same), it is determined whether the received illuminance value is smaller than the optimal value (S305).

As a result of the determination in step S305, when it is determined that the received illuminance value is smaller than the optimum value, the current I provided to the light source 201 is increased by a predetermined magnitude Δ to increase the brightness of the light source 201 and then to step S301. If it is confirmed that the received illuminance value corresponds to an optimum value (S306), the current I provided to the light source 201 is maintained as it is, and the process returns to step S3014 without changing the brightness of the light source 201 ( S307).

The power saving lighting system according to the present invention can be controlled not only in the automatic mode but also in the manual mode. Control by the manual mode is made through the operation of the keys 301, 302, 303 of the user control unit 300, which is the same as the prior art, and thus detailed description thereof will be omitted.

 Although the technical spirit of the present invention has been described in detail in the preferred embodiments, it should be noted that the above-described embodiments are for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

1 is a view showing an embodiment of a power saving lighting system according to the present invention.

Figure 2 is a block diagram schematically showing the configuration of the light with a built-in illuminance sensor.

Figure 3 is a block diagram schematically showing the configuration of the illumination is not built-in illuminance sensor.

4 to 6 is a flow chart illustrating a control method of a power saving type lighting system according to the present invention.

<Explanation of symbols for main parts of drawing>

100: sensor type lighting unit

200: non-sensor type lighting unit

101, 201: light source

102, 202: main control unit

103,203: current controller

104, 204: power supply

105, 205: communication unit

106,206: user input / output unit

107: illuminance sensor input unit

Claims (4)

Sensor type lighting units including an illumination sensor for measuring an illuminance of the first light source and the surroundings, and adjusting brightness of the first light source such that an illumination value measured by the illumination sensor reaches an optimum value; The light source includes a second light source and is distributed with the sensor-type lighting units in an indoor space where illumination is required, and receives an illuminance value from an adjacent sensor-type lighting unit, so that the received illuminance value reaches the optimum value. Non-sensor type lighting units for adjusting brightness; The sensor-type lighting unit may include: an illumination sensor input unit configured to read an illumination value measured by the illumination sensor and transmit it to the main controller; If the illuminance value from the illuminance sensor input is less than the optimum value, generate a control signal for increasing the current provided to the first light source, and if the illuminance value is greater than the optimum value, reduce the current provided to the first light source. A main control unit for generating a control signal for activating the control signal; A current controller configured to provide a first light source with a current according to a control signal from the main controller; Further comprising a communication unit for transmitting the illuminance value measured by the illuminance sensor to the adjacent non-sensor type lighting unit, The non-sensor type lighting unit may include a communication unit configured to receive an illumination value from the adjacent sensor type lighting unit; If the illuminance value from the communication unit is less than the optimum value, generate a control signal for increasing the current provided to the second light source, and if the illuminance value is greater than the optimum value, the control signal for reducing the current provided to the second light source. A main controller for generating a; And a current controller for supplying a current according to a control signal from the main controller to the second light source. delete delete delete

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