KR101228433B1 - Led light module capable of remote management - Google Patents

Abstract

PURPOSE: An LED lighting module remotely managed is provided to perform remote in various ways by performing control through an illuminance sensor or a motion sensor. CONSTITUTION: An LED lighting module(100) remotely managed includes a sensor unit(110), a control unit(120), a communication unit(130), and a lighting unit(140). The lighting unit groups or individualizes one or more LEDs. The lighting unit performs a function for emitting light according to a control command of the control unit. The communication unit performs a function for connecting plural LED lighting modules with a communication network. The communication unit is connected with a central control system or a control terminal for individually controlling all LED lighting modules through a communication network(200). [Reference numerals] (100) LED lighting module; (101) LED lighting module; (102) LED lighting module; (110) Sensor unit; (120) Control unit; (130) Communication unit; (140) Lighting unit; (200) Communication network

Description

LED LIGHT MODULE CAPABLE OF REMOTE MANAGEMENT}

The present invention relates to a technique for managing at least one LED lighting, and more particularly, to control the LED lighting managed through a sensor or manual command data in various ways, and to conveniently know the power consumption and failure of the LED lighting. The present invention relates to a technology for improving manageability of a plurality of LED lights such as network lights.

Recently, as interest in environmentally friendly technologies and power saving technologies has increased, interest in lighting technologies with low power consumption and low power consumption has increased. In particular, recently, various colors including white and warm white can be implemented, and there is a growing interest in LED lighting having a low power consumption and a long lifetime.

Indeed, in some cities in Korea, a pilot project is being conducted to replace streetlights with streetlights using LED lighting.In addition, streetlights, LED lighting projects have been actively implemented in various lighting markets such as security, indoor, and parking lights. ought.

LED lighting can be adjusted according to the power supply, and its advantages are highlighted by its semi-permanent lifespan. Accordingly, research into a technology for further reducing power by controlling the brightness of the installed LED lighting, as well as simply installing the lighting device using the LED lighting has been increasing day by day.

The LED lighting may control the brightness of the LED by adjusting a power supply to the LED module including the plurality of LED elements or the plurality of elements of the LED lighting unit. Therefore, in order to control the brightness of the LED lighting, a control means is usually connected to the driving unit of the LED module to adjust the size of the power applied to the LED module from the driving unit.

Meanwhile, in the case of LED lighting, as described above, since a plurality of lighting modules must be controlled manually or remotely at once, a large amount of communication data is consumed, and difficulties in managing each LED lighting module have been pointed out. Accordingly, there is a need for a technology that can control LED lighting in a variety of ways, and a technology that can efficiently manage LED lighting, along with a low communication data and a technique for controlling the speed at high speed. .

Accordingly, an object of the present invention is to provide a technique capable of controlling at least one LED lighting controlled through a sensor or manual command data quickly while consuming less data and controlling in various ways.

In addition, the present invention in the integrated management of at least one LED lighting, it is possible to easily and accurately know the power consumption and failure of each LED lighting, and to provide a technique for reducing the system load in management There is this.

In order to achieve the above objects, LED management module capable of remote management according to an embodiment of the present invention, the lighting unit including at least one LED lighting element; A sensor unit configured to collect sensing data on the surrounding environment situation within a preset range; Receiving at least one of control information which is information for controlling the illuminance of the LED illumination from a nearby LED lighting module or a control terminal and a sensing data collected from a sensor unit of the adjacent LED lighting module through a communication network, the sensing data and the A communication unit for transmitting at least one of the received control information to another adjacent LED lighting module; And a controller configured to control the illuminance of light irradiated from the lighting unit by using at least one of the sensing data, the sensing data collected from the sensor unit of the adjacent LED lighting module, and the control information.

The control unit may include a sensing data receiver configured to receive the sensing data from the sensor unit; A control command receiver configured to receive at least one of the sensing data and the control information collected from the sensor unit of the adjacent LED lighting module from the communication unit; An event determining unit generating a control command of the lighting unit according to at least one of the sensing data, the sensing data collected from the sensor unit of the adjacent LED lighting module, and the control information; And an illumination control unit controlling to change the illuminance of the lighting unit from the default illuminance according to the control command.

The control information preferably includes setting information for any one of at least one control mode and control command information corresponding to the control mode included in the setting information.

The control command information may include, when the control mode is a manual mode, a time point at which the illumination unit changes the illumination, a delay time required for the illumination unit to change the illumination, an illumination value when the illumination unit changes the illumination, and an illumination change at the illumination unit. It is preferable to include at least one of the information regarding the maintenance time of the illumination of the city.

The control command information may include, when the control mode is an illuminance sensing mode, at least one target illuminance value, a time point at which the illuminance of the illumination unit is changed to the at least one target illuminance value, and the at least one target illuminance value. It is also possible to include at least one of a delay time for changing the illuminance of and information about the holding time for each of the at least one target illuminance.

The event determining unit may generate a control command for real-time feedback control of the illuminance of the lighting unit such that the ambient illuminance collected from the illuminance sensor included in the sensor unit becomes the at least one target illuminance value.

The control command information may include a default illuminance value of illuminance of the illumination unit when the motion detection sensor included in the sensor unit does not detect the movement of the object when the control mode is the motion sensing mode, and when the movement of the object is detected. It may also include at least one of a sensing illuminance value, which is an illuminance of the illumination unit, a delay time required to change between the default illuminance value and the sensing illuminance value, and information about a holding time of the sensing illuminance value.

The control command information is a default target illuminance value, which is a target illuminance value when the motion detection sensor included in the sensor unit does not detect an object movement when the control mode is an illuminance and a motion sensing mode, and detects the movement of the object. It may also include at least one of a sensing target illuminance value which is a target illuminance value of a city, a delay time required for a change between the default target illuminance value and the sensing target illuminance value, and information about a holding time of the sensing target illuminance value. .

The event determiner feeds back the illuminance of the illumination unit in real time such that the ambient illuminance collected from the illuminance sensor included in the sensor unit becomes the default target illuminance value or the detection target illuminance value according to whether the object is detected. It is desirable to generate a control command to control.

The control unit may include at least one of at least one of the power consumption information consumed during a predetermined period of time in the lighting unit, information on whether the lighting unit is broken, and identification ID information of the LED lighting module including the lighting unit. It is preferable to further include; monitoring unit for transmitting to the management server or the control terminal through.

The monitoring unit calculates a power consumption of the lighting unit during the preset period by receiving an occurrence time of an event of changing the illuminance of the lighting unit in response to the control command and the control command corresponding to the generated event. It is desirable to.

The monitoring unit may be configured to change the default illuminance of the lighting unit included in the default power consumption, information on the occurrence time of the event, and the control command corresponding to the generated event using the illuminance value at the time of the default illuminance and the predetermined period value. The additional power consumption at the time of occurrence of the event is calculated using a value, and the default power consumption and the additional power consumption are added to calculate the power consumption of the lighting unit during the predetermined period.

When the monitoring unit determines that the illuminance value of the illuminating unit measured by the illuminance sensor installed in the illuminating unit is less than a predetermined threshold illuminance value, it is preferable that the monitoring unit generates information determined that a failure has occurred in the illuminating unit.

When it is determined that the power consumption information exceeds a predetermined power consumption value, the monitoring unit may generate information determined that a failure occurs in the lighting unit.

According to the present invention, the LED lighting can be controlled manually or controlled through an illumination sensor or a motion sensor, which can be remotely controlled in various ways, and at the same time, it is possible to reduce the power consumption by precisely controlling the illumination. In addition, by controlling the plurality of LED lighting modules by communicating between the LED modules through a communication unit mounted on the LED lighting module, it is possible to reduce the amount of data transmission and reception consumed for remote control.

On the other hand, since the amount of power consumed by each LED lighting module can also be measured using the value calculated from the event occurrence information and unit power consumption according to the control command transmitted without directly measuring the power, the LED lighting module directly measures the power. It can be computed or simply collected and collected in a centralized control system. Accordingly, the amount of data received from the LED lighting module for power measurement can be reduced.

1 is a block diagram of an LED lighting module capable of remote management according to an embodiment of the present invention.
2 is a detailed block diagram of a controller implemented according to an embodiment of the present invention.
3 to 8 are flowcharts for flow examples of functions performed by the LED lighting module according to an embodiment of the present invention.
9 is a graph illustrating an example of calculating the power consumption of the LED lighting module according to an embodiment of the present invention.

Hereinafter, an LED lighting module capable of remote management according to an embodiment of the present invention will be described with reference to the accompanying drawings.

In the following description, in order to clarify the understanding of the present invention, description of well-known technology for the features of the present invention will be omitted. The following embodiments are detailed description to help understand the present invention, and it should be understood that the present invention is not intended to limit the scope of the present invention. Therefore, equivalent inventions that perform the same functions as the present invention will also fall within the scope of the present invention.

In addition, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, in describing the component of this invention, terms, such as 1st, 2nd, A, B, (a), (b), can be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected to or connected to the other component, It should be understood that an element may be "connected," "coupled," or "connected."

1 is a block diagram of an LED lighting module capable of remote management according to an embodiment of the present invention.

Referring to FIG. 1, an LED lighting module 100 capable of remote management according to an embodiment of the present invention includes a sensor unit 110, a control unit 120, a communication unit 130, and an illumination unit 140. It features. In the following description, each component will be described in the order of function execution, not in order of identification number.

The lighting unit 140 includes at least one LED element in a grouped or individualized manner, and performs a function of irradiating light by receiving power according to a control command of the controller 120.

The lighting unit 140 may irradiate light in various irradiation forms according to the installation form of the LED elements installed in the lighting unit 140 at the irradiation target point. For example, it is possible to take various types of irradiation such as round, batwing, and line.

The LED elements installed in the lighting unit 140 may be individually powered or grouped to receive power. That is, each LED element may be individually controlled by receiving different power, or may be controlled by group by receiving different powers for each device group including a plurality of LED elements. Alternatively, the LED elements installed in the lighting unit 140 connected to one power source may be collectively controlled.

The sensor unit 110 performs a function of collecting the environment information of the target point or LED lighting module 100 to which the lighting unit 140 irradiates light. To this end, at least one sensor capable of sensing the surrounding environment information may be included in the sensor unit 110.

For example, the sensor 110 may include an illuminance sensor for measuring the illuminance of the surrounding to be described below, a motion sensor for detecting the movement of an object in the target irradiation point, and the like.

The sensor unit 110 transmits sensing data about collected environmental information to the controller 120 to change the illuminance of the lighting unit 140 according to the sensing data.

The communication unit 130 performs a function of connecting the plurality of LED lighting modules 100, 101, and 102 to a communication network. In addition, the communication unit 130 is connected to a control terminal (not shown) or a central control system (not shown) that controls all the LED lighting modules 100, 101, and 102 through the communication network 200, and each LED lighting module ( The control information for the 100, 101, 102 is transmitted to the control unit 120 of the corresponding LED lighting module, or the specific data generated from the control unit 120 is transferred to other LED lighting modules 101, 102, the control terminal, or the central control system. It performs the function of passing on.

In this case, the data transmitted from the communication unit 130 may include information for calculating power consumed by the lighting unit 140, power information consumed by the lighting unit 140, sensing data measured by the sensor unit 110, and other LED lighting modules. 101 and 102, and may include control information or sensing data received from the control terminal or the central control system.

In the present invention, the LED lighting module (100, 101, 102) are connected to each other via a communication network 200, for example, a short-range communication network. Control information from the central control system or the control terminal is individually transmitted to each of the LED lighting module (100, 101, 102), or when transmitting to one LED lighting module 100 through the communication network 200 LED lighting module 100 ) May be transferred from the communication unit 130 to other LED lighting modules 101 and 102.

In addition, the sensing data sensed by the sensor unit 110 may be transmitted to other LED lighting modules 101 and 102 through the communication unit 130.

Through this, the other LED lighting modules 101 and 102 may be controlled to receive the sensing data from the adjacent LED lighting module 100 so as to change the illuminance of the lighting in advance.

For example, when the control information is set so that the illumination of one LED lighting module 100 is bright when the movement of the object is detected, the sensing data indicating that the movement of the object is detected is different from the LED lighting module 101, 102. In order to be transmitted in turn, even if the movement of the object is not detected by controlling the brightness of the illumination in advance, it is possible to provide convenience when using the illumination.

In the present invention, the sensor is mounted on each LED lighting module (100, 101, 102), a separate sensor (not shown) may be provided to perform the above function.

Taking the parking lot as an example, when a plurality of lights inside the parking lot are connected through the communication network of the present invention, when the car enters the parking lot, the adjacent lights may be sequentially turned on. However, at the moment when the car enters the parking lot, the lighting closest to the entrance of the parking lot can be turned on only when the car actually enters and is detected by the motion sensor of the lighting.

To this end, if a separate sensor, that is, a sensor that does not include lighting, is installed at the parking lot entrance, the lighting near the parking lot entrance also receives sensing data of the sensor through the communication unit 130 and controls the lighting to be turned on accordingly. Can be.

Conventionally, in order to perform such a function, LED lights were separately installed and communication networks were separately installed, and sensors had to be installed separately. Accordingly, in order to manage LED lights in a network, all separately installed devices had to be controlled. As a result, the amount of data consumed for control was very large.

However, in the present invention, one LED lighting module 100 includes all of the above functions to control all the functions with only the identification information of one LED lighting module 100, LED Remote control is possible through communication between the lighting modules 100, 101, and 102, so that the amount of data consumed is reduced very much, and the accuracy of the control can be increased.

The data received from the communication unit 130 corresponds to the data transmitted from the communication unit 130, the sensing data measured by the corresponding LED lighting module (101, 102) from the adjacent LED lighting module (101, 102) or transmitted control May contain information. It may also include control information transmitted from a remote control terminal or a central control system.

The control unit 120 includes control information received by the communication unit 130 through the communication network 200 and sensing data collected from the sensor units of the adjacent LED lighting modules 101 and 102 and the sensor of the corresponding LED lighting module 100. The sensing data collected from the unit 110 is used to control the illuminance of light emitted from the lighting unit 140.

Detailed functions of the controller 120 will be described in detail later with reference to FIG. 2.

Through the above configurations, using the LED lighting module 100 according to an embodiment of the present invention, by installing the LED lighting module 100 in a desired place and setting only identification information thereof, the width, shape of the place And it is effective to manage the LED lights integrated regardless of the installation-based environment.

In addition, it is possible to simply control the LED lighting module 100 through the remote terminal using the short-range communication, there is an effect that the convenience of management can be increased. Convenience of management will be described in more detail with reference to FIG. 2.

2 is a detailed block diagram of the control unit 120 implemented according to an embodiment of the present invention.

Referring to FIG. 2, the controller 120 includes a sensing data receiver 121, a control command receiver 122, an event determiner 123, an illumination controller 124, and a monitor 125. .

The sensing data receiver 121 performs a function of receiving sensing data such as the above-mentioned peripheral illumination and motion detection information from the sensor unit 110. As described above, the control command receiving unit 122 performs a function of receiving at least one of sensing data and control information collected from the LED lighting modules 101 and 102 in proximity to the communication unit 130.

The control information may include setting information for any one of at least one control mode of the LED lighting module 100 that may be performed in the present invention, and control command information corresponding to each control mode included in the setting information. have.

That is, the control information includes setting information for operating the LED lighting module 100 in any one control mode, and detailed control command information necessary for operating the LED lighting module 100 in any one of the control modes. Will be.

In the present invention, four control modes can be switched. The control mode may include a manual mode, an illumination sensing mode, a motion sensing mode, and an illumination and motion sensing mode.

The manual mode is a mode for controlling the illuminance of the lighting unit 140 using only control command information included in the control information. To this end, when the control mode is the manual mode, the control command information includes the time of changing the illuminance of the lighting unit 140, the illuminance value to be changed, and the illuminance value of the illuminating unit 140 to be changed from the original illuminance value. At least one of a delay time, which is a time required to do so, and information about a time for maintaining the changed illuminance when the illuminance is changed may be included.

For example, if the illuminance is normally maintained at L1 and manually controlled to raise the illuminance to L2 from 7 pm to 6 am, the illuminance value information and the illuminance from 7 pm to 6 am The change time point and the illuminance holding time information may be included in the control command information.

Delay time refers to the time to slowly light up or darken, in order to solve the LED element damage caused by a sudden change in the illumination and the discomfort of the person receiving the light. For example, from 7 pm, the time for changing to the illuminance of L1 to L2 is set to 30 minutes, and the time for changing to the illuminance of L1 from L2 to L1 is also set to 30 minutes from 6 am, so that Can be set to control.

Meanwhile, the illuminance sensing mode refers to a mode in which the illuminance of the illumination unit 140 is changed in real time according to the ambient brightness, so that the ambient brightness is kept constant or changed according to the situation.

To this end, in the illumination sensing mode, the control command information includes at least one target illuminance value and a point of time at which the illuminance of the illumination unit 140 is changed to each of the target illuminance values, and the illuminance of the illumination unit 140 is changed to each target illuminance value. At least one of a delay time and information about a holding time for each target illuminance may be included.

When the illuminance sensing mode is set, a target illuminance for lighting is set, and the illumination unit 140 adjusts the brightness such that the ambient illuminance sensed by the sensor unit 110 corresponds to the target illuminance.

Meanwhile, the motion sensing mode refers to a mode of changing the illuminance of the lighting unit 140 according to whether the movement of the object is detected by the sensor unit 110.

To this end, in the motion sensing mode, the control command information includes the default illuminance value, which is the illumination intensity of the illumination unit 140, and the movement of the object when the movement of the object is not detected by the motion detection sensor included in the sensor unit 110. At least one of information on a sensing illumination value, which is the illumination intensity of the illumination unit 140, a delay time for changing the illumination between the default illumination value and the detection illumination value, and a holding time for which the detection illumination value is maintained after the movement is detected when the motion is detected. May be included.

Lastly, the illuminance and motion sensing mode is a mode for changing the illuminance of the illumination unit 140 to change the illuminance of the surroundings measured by the sensor unit 110 according to whether the movement of the object is detected by the sensor unit 110. Means.

To this end, the control command information includes a default target illuminance value which is a target illuminance when the movement of the object is not detected by the motion sensor included in the sensor unit 110, and a detection target which is the target illuminance when the movement of the object is detected. At least one of an illumination value, a change delay time between the default target illuminance value and the sensing target illuminance value, and information about a holding time for maintaining the sensing target illuminance value may be included.

As a result, when the motion of the object is not detected, the lighting unit 140 adjusts the amount of light irradiated by the user in real time to maintain the ambient illuminance with the default target illuminance value, and maintains when the motion of the object is detected. In order to maintain the ambient illuminance at the detection target illuminance value, feedback control of the amount of light irradiated in real time is performed.

The event determination unit 123 may perform a function of generating a control command for controlling the lighting unit 140 according to each control mode mentioned above. That is, when a motion is detected or when the illuminance is changed, or when an error between the surrounding illuminance and the target illuminance occurs in real time, it is determined that the corresponding event has occurred, and the illuminator of the illumination unit 140 is used as the target illuminance or the illuminance as the illuminant. A control command for changing the illuminance of 140 is generated.

In the case of the target illuminance, as described above, the event determiner 123 may generate a control command for feedback control of the illuminance of the illumination unit in real time when an error between the ambient illuminance value and the target illuminance value occurs in real time.

Meanwhile, the event determiner 123 calculates a failure status and power consumption, or transmits sensing data to a proximity LED lighting module, and provides the monitoring unit 125 with control information related to an event occurrence time and an event when the event occurs. I can deliver it.

The lighting controller 124 substantially controls the lighting unit 140 according to a control command transmitted from the event determining unit 123.

As described above, the monitoring unit 125 receives an event occurrence event, an event occurrence time, and control information related to the event from the event determination unit 123, and transmits it to the communication unit 130. The communication unit 130 receives the data and delivers the data to another nearby LED lighting module, the control terminal or the central control system.

In particular, the monitoring unit 125 may transmit information for calculating whether the LED lighting module has failed or power consumption to a control terminal or a central control system for managing each LED lighting module. This will be described later.

3 to 8 are flowcharts for flow examples of functions performed by the LED lighting module according to an embodiment of the present invention. In the following description, a description of overlapping portions with the description of FIGS. 1 and 2 will be omitted.

Referring to FIG. 3, the communication unit of the LED lighting module capable of remote management according to an exemplary embodiment of the present invention receives control information from the communication unit of the adjacent LED lighting module, and precisely the sensing data measured by the sensor unit of the LED lighting module close to the control information. Step S10 is performed. Thereafter, the communication unit transmits the sensing data measured by the sensor unit of the adjacent LED lighting module together with the control information and the sensing data measured by the sensor unit of the LED lighting module including the communication unit to another adjacent LED lighting module (S20). Done.

On the other hand, referring to Figure 4, the control unit of the LED lighting module receiving the control information, by using the setting information for any one of the above control modes included in the control information, of the LED lighting module including the control unit In step S30, the control mode is set.

Thereafter, the control information is analyzed to extract control command information corresponding to the control mode included in the control information (S40), thereby extracting a command for controlling the lighting unit in detail according to the control mode.

Thereafter, the controller executes each control mode according to the extracted control command information to perform the step of controlling the illuminance, that is, the brightness, of the lighting unit (S50).

In addition to FIG. 4, referring to FIG. 5, the control unit may perform step S60 of receiving sensing data from the sensor unit together with the control information.

Accordingly, the controller controls the brightness of the lighting unit of the LED lighting module according to the received sensing data and the control command information (S70). Thereafter, the control unit transmits the control result information and the like to the other LED lighting module through the communication unit (S80).

Through this, it is possible to control a plurality of LED lighting modules through communication between the LED lighting modules, it is possible to implement a function to naturally control a plurality of LED lighting modules.

Meanwhile, referring to FIG. 6, the flow of the controller as described above in each control mode is illustrated.

First, the controller distinguishes the control mode through steps S31, S32, S33, and S34 for determining whether the control mode is a manual mode, an illumination sensing mode, a motion sensing mode, or an illumination and motion sensing mode. Steps S31 to S34 may be performed by loading control mode information set in the controller.

When it is determined that the control mode is the manual mode, the controller is required to change the illuminance from the original illuminance value to the point in time of changing the illuminance of the illuminator, the illuminance value to be changed, and the illuminator value to be changed as mentioned above. At least one of extracting information about a delay time and a time for maintaining the changed illuminance when the illuminance is changed is performed (S41), and controlling the illuminance of the lighting unit according to the extracted information (S51). Perform

On the other hand, when it is determined that the control mode is the illuminance sensing mode, the control unit at least one target illuminance value, the timing of changing the illuminance of the illumination unit to each of the target illuminance value, the delay time of changing the illuminance of the illumination unit by each target illuminance value and In operation S42, at least one of information on a holding time for each target illuminance is extracted.

Thereafter, the controller performs a step of controlling feedback of illuminance of the lighting unit in real time so that the target illuminance is extracted according to the extracted information of illuminance of the surroundings (S52).

If it is determined that the control mode is the motion sensing mode, the control unit is the default illuminance value of the illumination intensity of the illumination unit when the movement of the object is not detected by the motion sensor included in the sensor unit, the illumination unit when the movement of the object is detected Extracting at least one of information on a sensing illuminance value, which is an illuminance of illumination, a delay time for changing the illuminance between the default illuminance value and the sensing illuminance value, and information on a holding time for which the sensing illuminance value is maintained after the movement is detected (S43) Perform Thereafter, in step S53 of controlling the illuminance of the lighting unit according to the extracted information.

When it is determined that the control mode is the illuminance and the motion sensing mode, the control unit may determine a default target illuminance value, which is a target illuminance when the movement of the object is not detected by the motion sensor included in the sensor unit, and when the movement of the object is detected. In operation S44, at least one of a detection target illuminance value that is a target illuminance, a change delay time between the default target illuminance value and the detection target illuminance value, and information about a holding time for maintaining the detection target illuminance value is extracted.

Subsequently, the controller performs a step of controlling feedback of illuminance of the lighting unit in real time so that the ambient illuminance sensed by the illuminance sensor becomes a target illuminance value corresponding to each event (S54).

According to the embodiment of FIG. 6, in the present invention, the LED lighting module can be controlled according to a management situation by implementing various control modes. Particularly, in the case of illuminance and motion sensing mode, the LED lighting module can be precisely minimized while minimizing power consumption. It is effective to control the illuminance of.

Referring to FIG. 7, an example of a flow of calculating power consumption in the monitoring unit of the aforementioned controller is illustrated. The embodiment of FIG. 7 may be simply performed not only in the monitoring unit but also in the control terminal of the central control system or the administrator.

First, the monitoring unit changes when the target illumination value or the illumination intensity value of the illumination unit is changed and when an event such as a situation in which an object is detected is generated, and each control command information corresponding to the event, that is, when the event occurs, is changed. Receiving information on the illuminance value, the delay time, the holding time, and the like from the above-described event generating unit (S100) is performed.

Subsequently, the control unit of the monitoring unit, the central control system, or the manager first performs a step (S110) of calculating power consumption in a preset monitoring period in a pre-change illuminance value, a general default illuminance value, and the like.

Thereafter, when an event occurs, an operation of calculating additional power consumption or reduced power consumption using the received information is performed (S120).

In operation S130, a total amount of power consumed as a result of performing the steps S110 and S120 is added to calculate the total power consumption consumed by the corresponding LED lighting module in a predetermined period (S130).

Thereafter, step S140 is performed in which the identification information of the LED lighting module and the total power consumption information for the predetermined period calculated by step S130 are transmitted to the central control system or the control terminal. Step S140 is a function that may be performed by the monitoring unit when power consumption is calculated in the monitoring unit. If the above function is performed in the control terminal of the central control system or the manager, the power consumption may be stored in the storage of the system or the terminal.

A detailed example of calculating total power consumption in FIG. 7 will be described with reference to FIGS. 8 and 9.

Referring to the flowchart of FIG. 8 and the graph 500 of FIG. 9, first, the calculating means sets the power consumption per unit time at the general illuminance value or the default illuminance value before the change to W0 (S150).

After that, the time at which the event occurs is changed to the illuminance value changed to t1, or the delay time required to change the illuminance value corresponding to W0 when the event is released to d is corresponded to the illuminance value changed at the event occurrence. In step S160, a power consumption per unit time is set to W1, and a time at which an event is last maintained, that is, a time at which a changed illuminance value is maintained at t2. On the other hand, the total measurement time for measuring the power consumption, that is, the above-mentioned predetermined period is set to td (S170).

In this case, referring to FIG. 9, assuming that power consumption is W0, power consumption P1 consumed during the total measurement time may be calculated as W0td. Afterwards, the additional power consumed by the occurrence of the event corresponds to the area of the right triangle and the area of the rectangle to be added, so that the additional power consumption P2 is calculated as (W1-W0) d + (W1-W0) t2. Can be. Accordingly, the total power consumption Wt is calculated as the sum of P1 and P2 (S180).

9 illustrates an example in the illuminance and motion sensing mode. In the graph 500 of FIG. 9, there is shown a graph of power 510 consumed as the illuminance of the actual lighting unit changes, and ideally power 520 consumed according to the illuminance that the illuminating unit should illuminate according to an event. have.

As the difference between the two powers 510 and 520 is changed as the illumination sensing mode is added to the motion sensing mode, as described above, the illumination of the lighting unit is changed as the feedback is controlled in real time to maintain the ambient illumination as the target illumination. Therefore, this error occurs.

In the present invention, since the illumination control of the illumination unit is changed in real time, and the graph of the embodiment of FIG. 9 is emphasized to compare the two powers 510 and 520, the power consumption 510 is measured when the actual power consumption is measured. It will be appreciated that the difference between 520 and 520 is negligible.

Therefore, even with the above calculation method, the total power consumption value can be calculated very accurately.

In order to calculate more accurate power consumption, a method of integrating a real time power consumption value with time may be used.

7 to 9, the present invention can accurately measure the power consumed by the LED lighting module by a very simple operation, the effective management of the power consumption of a plurality of LED lighting module There is.

The function of the LED lighting module that can be remotely managed according to the above-described embodiment of the present invention is applied to an application (which may include a program included in a platform or an operating system, which is basically installed in the terminal). It may be executed by the user, or may be executed by an application (ie, a program) installed directly on the terminal by an application providing server such as an application store server, an application, or a web server associated with the corresponding service. In this sense, the function of the LED lighting module that can be remotely managed according to the embodiment of the present invention described above is implemented as an application (that is, a program) that is basically installed in a terminal or directly installed by a user, and can be read by a computer such as a terminal. Can be recorded on a recording medium.

Such a program may be recorded on a recording medium that can be read by a computer and executed by a computer so that the above-described functions can be executed.

As described above, in order to execute the function of the LED lighting module that can be remotely managed according to each embodiment of the present invention, the above-described program is a computer language such as C, C ++, JAVA, machine language, etc., which can be read by a computer processor (CPU). It may include a code (Code) coded as.

The code may include a function code related to a function or the like that defines the functions described above and may include an execution procedure related control code necessary for the processor of the computer to execute the functions described above according to a predetermined procedure.

In addition, such code may further include memory reference related code as to what additional information or media needed to cause the processor of the computer to execute the aforementioned functions should be referenced at any location (address) of the internal or external memory of the computer .

In addition, when a processor of a computer needs to communicate with any other computer or server, etc., to perform the above-described functions, the code may be stored in a computer's communication module (e.g., a wired and / ) May be used to further include communication related codes such as how to communicate with any other computer or server in the remote, and what information or media should be transmitted or received during communication.

The functional program for implementing the present invention and the related code and code segment may be implemented by programmers of the technical field of the present invention in consideration of the system environment of the computer that reads the recording medium and executes the program, Or may be easily modified or modified by the user.

Examples of recording media that can be read by a computer recording a program as described above include, for example, a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical media storage device, and the like.

Also, the computer-readable recording medium on which the above-described program is recorded may be distributed to a computer system connected via a network so that computer-readable codes can be stored and executed in a distributed manner. In this case, any of at least one of the plurality of distributed computers may execute some of the functions presented above and transmit the result of the execution to at least one of the other distributed computers, and transmit the result The receiving computer may also perform some of the functions described above and provide the results to other distributed computers as well.

In particular, a computer-readable recording medium recording an application that is a program for executing a function of an LED lighting module capable of remote management according to each embodiment of the present invention may be an application store server, an application, or a corresponding service. It may be a storage medium (eg, a hard disk, etc.) included in an application provider server such as a web server associated with the application server, or the application providing server itself.

A computer capable of reading a recording medium recording an application, which is a program for executing a function of an LED lighting module that can be remotely managed according to an embodiment of the present invention, is not only a general PC such as a general desktop or a laptop, but also a smart phone, It may include a mobile terminal such as a tablet PC, personal digital assistants (PDAs), and mobile communication terminals, as well as to be interpreted as all computing devices.

In addition, a computer capable of reading a recording medium recording an application which is a program for executing a function of an LED lighting module capable of remote management according to an embodiment of the present invention may be a smart phone, a tablet PC, a personal digital assistant (PDA) and mobile communication. In the case of a mobile terminal such as a terminal, the application may be downloaded from the application providing server to a general PC and installed on the mobile terminal through a synchronization program.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all of the components may be selectively coupled to at least one. In addition, although all of the components may be implemented as one independent hardware, some or all of the components may be selectively combined to perform a part or all of the functions in one or a plurality of hardware. As shown in FIG. Codes and code segments constituting the computer program may be easily inferred by those skilled in the art. Such a computer program may be stored in a computer readable storage medium and read and executed by a computer, thereby implementing embodiments of the present invention. As a storage medium of the computer program, a magnetic recording medium, an optical recording medium, or the like can be included.

It is also to be understood that the terms such as " comprises, "" comprising," or "having ", as used herein, mean that a component can be implanted unless specifically stated to the contrary. But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

Claims (14)

An illumination unit including at least one LED lighting element;
A sensor unit configured to collect sensing data on the surrounding environment situation within a preset range;
Receiving at least one of control information which is information for controlling the illuminance of the LED illumination from a nearby LED lighting module or a control terminal and a sensing data collected from a sensor unit of the adjacent LED lighting module through a communication network, the sensing data and the A communication unit for transmitting at least one of the received control information to another adjacent LED lighting module; And
And a controller configured to control illuminance of light emitted from the lighting unit by using at least one of the sensing data, the sensing data collected from the sensor unit of the adjacent LED lighting module, and the control information.
The control unit,
A sensing data receiver configured to receive the sensing data from the sensor unit;
A control command receiver configured to receive at least one of the sensing data and the control information collected from the sensor unit of the adjacent LED lighting module from the communication unit;
An event determining unit generating a control command of the lighting unit according to at least one of the sensing data, the sensing data collected from the sensor unit of the adjacent LED lighting module, and the control information; And
And a lighting control unit controlling to change the illuminance of the lighting unit from the default illuminance according to the control command.
The control information includes:
Setting information for any one of at least one control mode and control command information corresponding to the control mode included in the setting information,
The control command information,
When the control mode is the illuminance and motion sensing mode,
The default target illuminance value which is a target illuminance value when the motion detection sensor included in the sensor unit does not detect the movement of the object, the detection target illuminance value which is the target illuminance value when detecting the movement of the object, the default target illuminance value and the detection And at least one of a delay time for changing between target illuminance values and information regarding a holding time of the detection target illuminance value,
The control unit,
The at least one adjacent LED lighting module includes at least one of information for calculating power consumption consumed for a predetermined period of time in the lighting unit, information on whether the lighting unit is broken, and identification ID information of the LED lighting module including the lighting unit. Further comprising; Monitoring unit for transmitting to the management server or the control terminal through,
The monitoring unit,
The occurrence time of the event of changing the illuminance of the lighting unit corresponding to the control command and the control command information corresponding to the generated event are extracted, and among the information included in the control command information, The default power consumption is calculated using an illuminance value and the predetermined period value, and the event is generated using the information on the occurrence time of the event and the changed illuminance value of the lighting unit included in the control command corresponding to the generated event. And calculating the power consumption by adding the default power consumption and the additional power consumption after calculating the additional power consumption of the city. delete delete The method of claim 1,
The control command information,
If the control mode is a manual mode,
And at least one of information about a time of changing the illuminance of the lighting unit, a delay time required to change the illuminance of the lighting unit, an illuminance value when changing the illuminance of the lighting unit, and a time of maintaining the illuminance when changing the illuminance of the lighting unit. LED lighting module capable of remote management, characterized in that. The method of claim 1,
The control command information,
When the control mode is the illuminance sensing mode,
At least one target illuminance value, a time point of changing the illuminance of the illumination unit to the at least one target illuminance value, a delay time required to change the illuminance of the illuminating unit to the at least one target illuminance value, and the at least one target LED management module for remote management, characterized in that it comprises at least one of information about the holding time for each of the illuminance. The method of claim 5,
The event determination unit,
LED control module for remote management, characterized in that for generating a control command for real-time feedback control of the illuminance of the illumination unit such that the ambient illuminance collected from the illuminance sensor included in the sensor unit becomes the at least one target illuminance value. The method of claim 1,
The control command information,
When the control mode is a motion sensing mode,
A default illuminance value which is an illuminance of the illumination unit when the motion detection sensor included in the sensor unit detects no movement of an object, a sensing illuminance value which is an illuminance of the illumination unit when detecting the movement of the object, the default illuminance value and the And at least one of a delay time for changing between sensed illuminance values and information regarding a holding time of the sensed illuminance values. delete The method of claim 1,
The event determination unit,
A control command for feedback control of the illuminance of the illumination unit in real time such that the peripheral illuminance collected from the illuminance sensor included in the sensor unit becomes the default target illuminance value or the detection target illuminance value according to whether the object is detected for movement of the object; LED lighting module capable of remote management, characterized in that for generating. delete delete delete The method of claim 1,
The monitoring unit,
And when the illuminance value of the illuminator measured by the illuminance sensor installed in the illuminator is less than a predetermined threshold illuminance value, generates information indicating that a failure has occurred in the illuminator. The method of claim 1,
The monitoring unit,
If it is determined that the power consumption information exceeds a predetermined power consumption value, LED management module capable of remote management, characterized in that for generating information determined that the failure in the lighting unit.

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