KR20200075233A - Lighting control system to control flexible LED lighting equipment - Google Patents

Abstract

A lighting control system includes: a plurality of flexible LED lighting equipment with different power consumption; a common control device that supplies driving power to one of the plurality of flexible LED lighting equipment while automatically detecting power consumption of each connected flexible LED lighting equipment and adjusting the size of the driving power; and a portable terminal that exchanges data signals with the common control device using a wireless communication method, and sets brightness information and color temperature information using an installed lighting control application.

Description

Lighting control system to control flexible LED lighting equipment

The present invention relates to a lighting device, and more particularly, to a lighting control system for controlling a flexible LED lighting device.

In order to construct LED (LED) lighting, an LED light source device, a control device for controlling the LED, and a power supply device for supplying power are required.

Conventional LED lighting devices have many structures in which the LED light source device and the control device are integrally formed, and the power supply device may be separated or the power supply device may be integrally formed.

The general LED lighting device is composed of a plastic or aluminum case, but the flexible LED lighting has an advantage that does not require a device.

The flexible LED lighting device has the advantages of being lighter, more portable, and more convenient to use than the existing structured LED lighting, but the size and structure are different depending on the power consumption, so that the control device for driving it is one to one according to each light source. It has the disadvantage of being used.

That is, when there are a plurality of flexible LED lighting devices, there is a disadvantage that a control device for controlling each is required separately.

The present invention has been proposed to solve the above technical problems, and supplies driving power to any one of the flexible LED lighting devices, but automatically detects the power consumption of each connected flexible LED lighting device. It provides a lighting control system that can adjust the size of the driving power.

In addition, it provides a lighting control system that can remotely set the brightness information and color temperature information using a lighting control application.

According to an embodiment of the present invention for solving the above problem, to supply a driving power to a plurality of flexible LED lighting equipment having different power consumption, and any one of the plurality of flexible LED lighting equipment , A common control device that automatically detects the power consumption of each connected flexible LED lighting device to adjust the size of the driving power supply, and exchanges data signals with the common control device using a wireless communication method, and uses an installed lighting control application A lighting control system including a portable terminal for setting brightness information and color temperature information is provided.

In addition, the plurality of flexible LED lighting devices included in the present invention includes a non-volatile memory for storing power consumption information and a unique ID, and the common control device is stored in the non-volatile memory when connected to the flexible LED lighting device. It is characterized by adjusting the size of the driving power source based on the information.

In addition, the flexible LED lighting device included in the present invention is driven with the maximum power consumption in the initial trimming section defined for a predetermined time from the time when it is connected to the common control device, and the common control device is the initial trimming section It is characterized in that the size of the driving power is adjusted based on power consumption.

In addition, the plurality of flexible LED lighting devices included in the present invention are divided into a master and a slave, respectively, and after the master exchanges data signals with the common control device, it is characterized in that it is transmitted to the slave device.

The lighting control system according to an embodiment of the present invention may supply driving power to any one flexible LED lighting device among a plurality of flexible LED lighting devices, and automatically detects power consumption of each connected flexible LED lighting device to detect the power consumption. Can be adjusted. Therefore, there is an advantage in that a plurality of flexible LED lighting devices can be controlled using one common control device.

In addition, brightness information and color temperature information can be set remotely by using the lighting control application of the smartphone.

1 is a conceptual diagram of a lighting control system 1 according to an embodiment of the present invention
2 is a block diagram of the lighting control system 1 according to the first embodiment
3 is a block diagram of the lighting control system 1 according to the second embodiment
4 is a block diagram of a lighting control system 1 according to a third embodiment
5 is an exemplary view of a lighting control application

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings in order to describe in detail that a person skilled in the art to which the present invention pertains can easily implement the technical spirit of the present invention.

1 is a conceptual diagram of a lighting control system 1 according to an embodiment of the present invention.

The lighting control system 1 according to the present embodiment includes only a brief configuration for clearly explaining the technical idea to be proposed.

Referring to FIG. 1, the lighting control system 1 includes at least one flexible LED lighting device 100, a common control device 200, and a portable terminal 300.

In this embodiment, it is assumed that the plurality of flexible LED lighting devices 100 have different power consumption. That is, the flexible LED lighting device 100 has different power consumption depending on the area, the maximum amount of light, the number of colors, and the color temperature.

The common control device 200 supplies driving power to any one of the flexible LED lighting devices 100, and automatically detects the power consumption of each connected flexible LED lighting device to automatically detect the size of the driving power. Adjust.

For example, when the plurality of flexible LED lighting devices 100 include non-volatile memory for storing power consumption information and unique IDs, the common control device 200 is non-volatile when connected to the flexible LED lighting device 100 The size of the driving power is adjusted based on the information stored in the memory.

That is, when the common control device 200 is connected to the flexible LED lighting device 100 for the first time, a method of adjusting the size of the driving power by receiving power consumption information and a unique ID from a non-volatile memory may be applied. Since the flexible LED lighting device 100 is identified by a unique ID, the process of reading the information of the nonvolatile memory may be omitted when connecting after the first time.

At this time, the common control device 200 may periodically repeat the process of reading the information of the nonvolatile memory every predetermined number of times based on the number of times the unique ID is accessed. For example, the process of re-reading the information of the nonvolatile memory may be performed every four times.

For another example, the flexible LED lighting device 100 may be driven with the maximum power consumption in the initial trimming period defined for a predetermined time from the time when it is connected to the common control device 200. Therefore, the common control device 200 can detect the power consumption of the initial trimming section and adjust the size of the driving power supply based on the detected power consumption. At this time, the flexible LED lighting device may be configured such that the maximum power consumption is driven by the dummy element so that the flexible LED lighting device does not emit light.

The portable terminal 300 exchanges data signals with the common control device 200 using a wireless communication method, and sets brightness information and color temperature information using an installed lighting control application.

For reference, a portable terminal is a generic term for devices that can be used while being carried by a user, such as a mobile phone, a smart phone, and a smart pad.

2 is a block diagram of a lighting control system according to a first embodiment.

Referring to FIG. 2, the lighting control system may include at least one flexible LED lighting device 100, a common control device 200, a portable terminal 300, and a switching means 210.

In this embodiment, it is assumed that the plurality of flexible LED lighting devices 100 have different power consumption. That is, the flexible LED lighting device 100 has different power consumption depending on the area, the maximum amount of light, and the number of colors.

The common control device 200 supplies driving power to any one of the flexible LED lighting devices 100, and automatically detects the power consumption of each connected flexible LED lighting device to automatically detect the size of the driving power. Adjust. Since the common control device 200 and the flexible LED lighting device 100 can be separated from each other, the common control device 200 can be connected to one selected flexible LED lighting device 100.

For reference, the output port of the common control device 200 may be composed of two outputs for each number of colors. For example, a single color can have 2 output lines and 2 composite colors can have 4 output lines.

When comparing a flexible LED lighting device having a 50W single light source and a flexible LED lighting device having a 100W single light source, a difference in current or voltage occurs in the output port of the common control device 200.

The common control device 200 converts the difference value to a digital value, and then determines the type or power consumption of the light source based on this. At this time, the current and voltage changes of the output port are simultaneously judged, so that a light source suitable for the output is output when the satisfying condition is met. That is, a method of determining the type or power consumption of a light source after simultaneously determining the rate of change of current and voltage for a predetermined time and comparing it with a preset reference condition (satisfying condition) may be used.

When the plurality of flexible LED lighting devices 100 include non-volatile memory for storing power consumption information and unique IDs, the common control device 200 is stored in the non-volatile memory when connected to the flexible LED lighting device 100 Adjust the size of the driving power source based on the information.

That is, when the common control device 200 is connected to the flexible LED lighting device 100 for the first time, a method of adjusting the size of the driving power by receiving power consumption information and a unique ID from a non-volatile memory may be applied. Since the flexible LED lighting device 100 is identified by a unique ID, the process of reading the information of the nonvolatile memory may be omitted when connecting after the first time.

At this time, the process of reading the information of the nonvolatile memory may be periodically repeated every predetermined number of times based on the number of times the unique ID is accessed. For example, the process of re-reading the information of the nonvolatile memory may be performed every four times.

In addition, the flexible LED lighting device 100 may be driven with the maximum power consumption in the initial trimming period defined for a predetermined time from the time when it is connected to the common control device 200. Therefore, the common control device 200 can detect the power consumption of the initial trimming section and adjust the size of the driving power supply based on the detected power consumption.

The common control device 200 may configure a data table to adjust the output (driving power). For example, in the case of a 50W composite lighting, it should have two data values, which are brightness and color.

The brightness can be set to have 0 to 100 steps, and the color is configured to set a color temperature of 2700k to 6500k.

That is, the common control device 200 stores the brightness data of 0 to 100 levels of brightness at a color temperature of 6500K as a table, and stores the brightness data of 0 to 100 levels at a color temperature of 6400k as a table, depending on the control of the lighting control application. After using the data stored in the table or automatically determining the maximum power consumption of the flexible LED lighting device 100, the driving power corresponding to the color temperature and brightness value having the highest power consumption may be output.

The portable terminal 300 exchanges data signals with the common control device 200 using a wireless communication method, and sets brightness information and color temperature information using an installed lighting control application.

The switching means 210 may be composed of a device of a manual switching type or a device that is automatically switched under control of a lighting control application.

The passive element is a method in which any one of the flexible LED lighting devices 100 of the plurality of flexible LED lighting devices 100 is connected to the common control device 200 by user manipulation.

In addition, the automatic element is a method in which any one of the plurality of flexible LED lighting devices 100 is automatically connected to the common control device 200 under the control of the lighting control application.

3 is a block diagram of a lighting control system according to a second embodiment.

Referring to FIG. 3, the lighting control system may include at least one flexible LED lighting device 100, a common control device 200, and a portable terminal 300.

In this embodiment, it is assumed that the plurality of flexible LED lighting devices 100 have different power consumption. That is, the flexible LED lighting device 100 has different power consumption depending on the area, the maximum amount of light, and the number of colors.

The common control device 200 supplies driving power to any one of the flexible LED lighting devices 100, and automatically detects the power consumption of each connected flexible LED lighting device to automatically detect the size of the driving power. Adjust.

For example, when the plurality of flexible LED lighting devices 100 include non-volatile memory for storing power consumption information and unique IDs, the common control device 200 is non-volatile when connected to the flexible LED lighting device 100 The size of the driving power is adjusted based on the information stored in the memory.

That is, when the common control device 200 is connected to the flexible LED lighting device 100 for the first time, a method of adjusting the size of the driving power by receiving power consumption information and a unique ID from a non-volatile memory may be applied. Since the flexible LED lighting device 100 is identified by a unique ID, the process of reading the information of the nonvolatile memory may be omitted when connecting after the first time.

At this time, the process of reading the information of the nonvolatile memory may be periodically repeated every predetermined number of times based on the number of times the unique ID is accessed. For example, the process of re-reading the information of the nonvolatile memory may be performed every four times.

For another example, the flexible LED lighting device 100 may be driven with the maximum power consumption in the initial trimming period defined for a predetermined time from the time when it is connected to the common control device 200. Therefore, the common control device 200 can detect the power consumption of the initial trimming section and adjust the size of the driving power supply based on the detected power consumption.

The portable terminal 300 exchanges data signals with the common control device 200 using a wireless communication method, and sets brightness information and color temperature information using an installed lighting control application.

The common control device 200 is simultaneously connected to the plurality of flexible LED lighting devices 100, and is configured to supply driving power to each.

The common control device 200 automatically checks the power consumption of each of the plurality of flexible LED lighting devices 100, and then automatically adjusts the size of the driving power in consideration of the power consumption of each flexible LED lighting device.

4 is a configuration diagram of a lighting control system 1 according to a third embodiment.

Referring to FIG. 4, the lighting control system may include at least one flexible LED lighting device 100, a common control device 200, and a portable terminal 300.

In this embodiment, it is assumed that the plurality of flexible LED lighting devices 100 have different power consumption. That is, the flexible LED lighting device 100 has different power consumption depending on the area, the maximum amount of light, and the number of colors.

The common control device 200 supplies driving power to any one of the flexible LED lighting devices 100, and automatically detects the power consumption of each connected flexible LED lighting device to automatically detect the size of the driving power. Adjust.

For example, when the plurality of flexible LED lighting devices 100 include non-volatile memory for storing power consumption information and unique IDs, the common control device 200 is non-volatile when connected to the flexible LED lighting device 100 The size of the driving power is adjusted based on the information stored in the memory.

That is, when the common control device 200 is connected to the flexible LED lighting device 100 for the first time, a method of adjusting the size of the driving power by receiving power consumption information and a unique ID from a non-volatile memory may be applied. Since the flexible LED lighting device 100 is identified by a unique ID, the process of reading the information of the nonvolatile memory may be omitted when connecting after the first time.

At this time, the process of reading the information of the nonvolatile memory may be periodically repeated every predetermined number of times based on the number of times the unique ID is accessed. For example, the process of re-reading the information of the nonvolatile memory may be performed every four times.

For another example, the flexible LED lighting device 100 may be driven with the maximum power consumption in the initial trimming period defined for a predetermined time from the time when it is connected to the common control device 200. Therefore, the common control device 200 can detect the power consumption of the initial trimming section and adjust the size of the driving power supply based on the detected power consumption.

The portable terminal 300 exchanges data signals with the common control device 200 using a wireless communication method, and sets brightness information and color temperature information using an installed lighting control application.

Meanwhile, the plurality of flexible LED lighting devices 100 may be divided into a master and a slave, respectively.

After the master of the flexible LED lighting device 100 exchanges data signals with the common control device 200, it operates to transmit data signals to the slave devices. Here, the data signal includes brightness information, color temperature information, and channel information.

5 is an exemplary view of a lighting control application.

Referring to FIG. 5, the operation of the flexible LED lighting device 100 can be remotely controlled using the lighting control application installed in the portable terminal 300.

The lighting control application is configured to assign a plurality of flexible LED lighting devices 100 to each channel, to designate a master and a slave, and to adjust color temperature, brightness information, and the like.

The lighting control application of the portable terminal 300 and the common control device 200 may be configured to exchange data with each other using a wireless communication method, that is, a Bluetooth communication method or a Wi-Fi (WIFI) communication method.

The lighting control application is configured to set a password for each flexible LED lighting device 100 or a common control device 200, and may proceed to distinguish between a master and a slave. At this time, each channel may be set based on the address given to each flexible LED lighting device 100.

On the other hand, when the lighting control application transmits channel information, brightness information, and color temperature information to a flexible LED lighting device designated as a master, the master transmits channel information, brightness information, and color temperature information to the nearest slave. In addition, the slave transmits channel information, brightness information, and color temperature information to neighboring slaves. Each slave checks its brightness information and color temperature information based on the channel information, and then emits light at the color temperature of the corresponding brightness.

That is, since the communication module is built in the master and the plurality of slaves, it is possible to perform a function of sharing control signals of the common control device 200 while sequentially transmitting data. The separation distance between the master and the plurality of slaves can be estimated based on the intensity of the data signal.

The user may set the lighting information (flashing pattern, brightness information, color temperature information) using the lighting control application of the portable terminal 300,

When a separate server is provided, the server collects the usage information of a plurality of users in the lighting control application of the portable terminal 300 to grasp the user's preferred lighting information and utilize it for future product improvement and derivative development. have.

In addition, since the server collects even the shape information (size) of the flexible LED lighting apparatus 100, it is possible to periodically transmit recommended lighting information corresponding to the shape information (size) of the lighting apparatus to a user who uses the lighting control application. That is, it is possible to download and use the recommended setting data from the server without the user having to directly generate the setting data.

For reference, the case of the common control device 200 is applied with a heat dissipation system capable of maintaining a temperature of 50 degrees Celsius or less. That is, a ceramic heat sink instead of aluminum is basically used, and heat is dissipated by applying a heat sink around the output port of the common control device 200.

The common control device 200 is equipped with an LCD screen to display the control status, and can check the color temperature and brightness numerically. A battery pack may be mounted on the rear surface of the common control device 200 in a V-MOUNT manner, and the movement or mounting of the product may be conveniently performed by D-RING on the upper surface. In addition, it is configured to remotely control within 20 meters using the lighting control application of the portable terminal 300.

The lighting control system according to an embodiment of the present invention may supply driving power to any one flexible LED lighting device among a plurality of flexible LED lighting devices, and automatically detects power consumption of each connected flexible LED lighting device to detect the power consumption. Can be adjusted. Therefore, there is an advantage in that a plurality of flexible LED lighting devices can be controlled using one common control device.

In addition, brightness information and color temperature information can be set remotely by using the lighting control application of the smartphone.

As such, those skilled in the art to which the present invention pertains will appreciate that the present invention may be implemented in other specific forms without changing its technical spirit or essential features. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims rather than the above detailed description, and it should be interpreted that all changes or modified forms derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention. do.

100: flexible LED lighting equipment
200: common control device
300: portable terminal
210: switching means

Claims (4)

A plurality of flexible LED lighting devices having different power consumption;
A common control device that supplies driving power to any one of the plurality of flexible LED lighting devices, and automatically detects power consumption of each connected flexible LED lighting device to adjust the size of the driving power; And
A portable terminal exchanging data signals with the common control device using a wireless communication method and setting brightness information and color temperature information using an installed lighting control application;
Lighting control system comprising a.
According to claim 1,
The plurality of flexible LED lighting devices include a non-volatile memory that stores power consumption information and a unique ID, and the common control device is based on the information stored in the non-volatile memory when connected to the flexible LED lighting device. Lighting control system characterized in that to adjust the size of.
According to claim 1,
The flexible LED lighting device is driven with the maximum power consumption in the initial trimming period defined for a predetermined time from the time when it is connected to the common control device,
The common control device is a lighting control system, characterized in that for adjusting the size of the driving power supply based on the power consumption of the initial trimming section.
According to claim 1,
The plurality of flexible LED lighting devices are divided into master and slave respectively,
After the master exchanges data signals with the common control device, the lighting control system is characterized in that it is transmitted to the slave device.

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