KR100887919B1 - Multi-tab control system - Google Patents

Abstract

The present invention relates to a multi-tap control system for efficiently managing power of a multi-tap using Zigbee.

The multi-tap control system according to the present invention includes a Zigbee multi-tap for supplying power to a device using electricity based on the Zigbee communication protocol; And a management module for controlling power by bidirectionally communicating with the ZigBee power strip under the ZigBee communication protocol.

By such a configuration, the present invention can more easily and efficiently turn on and off the power of the power strip in an office or at home to safely use or save electricity.

Zigbee, Multi-tap

Description

Multi-tap control system {MULTI-TAB CONTROL SYSTEM}

1 is a view showing a multi-tap control system according to a first embodiment of the present invention.

2 is a diagram illustrating a Zigbee multi-tap according to a first embodiment of the present invention.

3 is a diagram illustrating a multi-tap control system according to a second embodiment of the present invention.

4 to 5 are diagrams illustrating a multi-tap control system according to a third embodiment of the present invention.

6 is a diagram showing that the multi-tap control system according to the first to third embodiments of the present invention is installed in an office, a factory, or a home.

<Explanation of Signs of Major Parts of Drawings>

100: Zigbee multi-tap 102: a plurality of plug socket

104: first Zigbee communication module 106: first MCU

108: function setting unit 114: ID setting unit

122: time setting switch 124: alarm absence

200: management module 202: second Zigbee communication module

204: second MCU 206: input unit

208: display unit

The present invention relates to a multi-tap, and more particularly, to a multi-tap control system for efficiently managing power using ZigBee.

In general, electronic products such as computers and home theaters that are commonly used in homes or offices are composed of various peripheral devices. At this time, various peripheral devices such as a computer or a home theater are mainly used with a power strip that can be easily connected in a batch to receive power.

These power strips are often installed in the corners of the home or office, behind the floor, or on the back of electronic equipment. It is very inconvenient to switch on or off the power switch when leaving or leaving the office. Will be

At this time, the multi-tap causes minute electricity to flow to the electronic products which are not used, and waste energy or cause a fire due to an external sudden overload.

Accordingly, in order to solve the above problems, the present invention is to provide a multi-tap control system for efficiently managing a multi-tap using ZigBee.

Multi-tap control system according to an embodiment of the present invention for achieving the above technical problem is a multi-tap for supplying power to a device using electricity based on the Zigbee communication protocol; It is configured to include a management module for controlling the power by bidirectional communication with the multi-tap under the Zigbee communication protocol.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings and embodiments.

1 is a view showing a multi-tap control system of the present invention, Figure 2 is a view showing a Zigbee multi-tap of the present invention.

1 and 2, the multi-tap control system of the present invention bidirectional communication with the ZigBee power strip 100 for supplying power to the device using electricity under the ZigBee communication protocol, and the ZigBee power strip 100 under the ZigBee communication protocol It comprises a management module 200 to control the power supply.

ZigBee is a hardware and software standard based on IEEE 802.15.4 that can transmit data at speeds of 20 to 250 Kbps over short distances of 1 to 100 m. One of ZigBee's most notable features is its low power consumption. It stays in 'sleep' mode until it sends a signal, so the power consumption is very low, so the battery can last from months to years, much simpler than Bluetooth or WLAN protocols, which is advantageous for miniaturization, and thus implementing Zigbee in the system The cost is also low.

Subsequently, ZigBee configures a network by connecting a router node around a single coordinator. ZigBee's addressing method supports the connection of 2 ¹⁶ = 65,536 nodes with 16-bit addresses per network.

Then, ZigBee uses 16 channels in the 2400 to 2483.5 MHz frequency band to reduce radio interference and other wireless products, and add encryption to the ZigBee standard to enhance the stability and security of wireless. .

In addition, although Zigbee communication mode is based on Master-Slave method, point-to-point networking called 'Mesh Mode' is possible, so that many devices contained in one band have the same level and are bidirectional. It has the advantage of communicating.

Although ZigBee has been briefly described above, more specifically, ZigBee is a standard technology for home automation and data networks with low transmission speeds. Remote control of various devices is possible with the touch of a button and dial-up via the Internet. This is where we start to use home automation more conveniently.

The IEEE 802.15.4 Task Group is standardizing PHY and MAC, while the ZigBee Alliance is standardizing PHY, MAC, Data Link, Network, and Application Layer. Dual PHY type uses 2.4GHz, 868 / 915MHz frequency band, DSSS (Direct Sequence Spread Spectrum) for modem, CSMA / CA for MAC, and data rates of 20 ~ 250Kbps.

In addition, the communication distance is about 100 ~ 500m, the power consumption is less than 500㎼, low power consumption.

In the present invention, based on the ZigBee-based technology as described above, it is possible to control a plurality of multi-taps in the office, factory or home by radio frequency communication.

The Zigbee multi-tap 100 is a plurality of plug sockets 102 and a first microcontroller circuit unit (MCU) 106 that is in charge of information processing and controls the plurality of plug sockets 102 according to signals of the management module 200. Wow; The first Zigbee module 104 and the plurality of plug sockets 102 wirelessly communicating with the management module 200 in both directions based on the ZigBee-based information processed by the first MCU 106 are provided with functions such as time setting and overload detection. It is configured to include a function setting unit 108 to provide.

The plurality of plug sockets 102 are formed so that power can be supplied by plugging in a device that uses electricity. At this time, each plug socket 102 is configured to include a socket switch 118 and the locking device (112).

The locking device 112 is formed so that each plug socket 102 can be driven independently. Here, the locking device 112 is configured to supply a control signal to the first MCU 106 and to supply or cut power according to a user setting for each plug socket 102. At this time, the control signal supplied by the locking device 112 to the first MCU 106 is set to have priority over the control signal supplied by the first MCU 106 to each plug socket 102.

The socket switch 118 is formed to supply or cut off the power supplied to each plug socket 102. In this case, the socket switch 118 may be set to supply or cut off power supplied to each plug socket 102 by a user, and may be supplied to each plug socket 102 by a control signal of the first MCU 106. Allow power to be turned on or off.

The first MCU 106 is responsible for information processing, and processes the control signal transmitted and received from the first ZigBee communication module 104 by the management module 200 to each plug socket 102 formed in the ZigBee power strip 100. It is configured to supply or cut off power. In this case, the first MCU 106 may be configured to supply a plurality of plug sockets 102 with functions such as ID setting, time setting, and overload detection set in the function setting unit 108.

The first Zigbee communication module 104 is configured to communicate in both directions with the management module 200 supporting the Zigbee communication protocol. Here, the first Zigbee communication module 104 supplies a control signal received from the management module 200 to the first MCU 106. In this case, the first Zigbee communication module 104 is connected to the first MCU 106 may include not only a function for Zigbee communication, but also a PAN network formation, management, and routing function.

In addition, a communication method for connecting between the first MCU 106 and the first Zigbee communication module 104 may include a Serial Peripheral Interface (SPI), a Serial Communications Interface (SCI), a Universal Synchronous / Asynchronous Receiver Transmitter (UART), and an I2C. Is formed to communicate with.

The function setting unit 108 is formed to provide a function to the plurality of plug sockets 102. Here, the function setting unit 108 provides a function set by the user to each plug socket 102. In this case, the function setting unit 108 may include an ID setting unit 114 for setting an ID (Identification) of the Zigbee power strip 100, a time setting unit 116 for setting a use time, and a plurality of plug sockets ( 102 is configured to include an overload detection unit 120 for detecting a load.

The ID setting unit 114 is formed to identify each ZigBee multi-tap 100 installed. In this case, the ID setting unit 114 supplies the first MCU 106 to compare the data received by the first ZigBee module 104 with the set ID when the management module 200 calls the ZigBee multi-tap 100. In this case, the ID setting unit 114 may store the ID set by the user in the first MCU 106.

The time setting unit 116 is formed to set a use time for each plug socket 102. At this time, the time setting unit 116 is configured to set the time by counting a predetermined time (Count) by the first MCU 106 the number of times pressed by the time setting switch 122 to set the time. Here, the time setting unit 116 may be configured to include a display unit not shown to check the set time.

The overload detection unit 120 is formed to detect an overload on each plug socket 102. At this time, the overload detection unit 120 determines whether the overload by measuring the current supplied to each plug socket (102). Here, the overload detection unit 120 informs the user through the notification unit 111 at the time of overload, and cuts off the power supplied to the Zigbee power strip 100 from the main power breaker 110.

The main power cutoff unit 110 is formed to cut off the power supplied from the main power line 126. In this case, when the overload detection unit 120 detects an overload, the main power cutoff unit 110 is supplied to the plurality of plug sockets 102 from the main power line 126 by a control signal of the first MCU 104. Form to cut off the power.

The alarm unit 111 includes an alarm member 124 and a reset switch 128.

The alarm member 124 is connected to the first MCU 106 is formed to notify the user when an overload occurs in each plug socket (102).

The reset switch 128 is formed to reuse the Zigbee power strip 100 by resetting the power cut off by the overload detecting unit 120 after checking the connection state.

The management module 200 outputs a control signal for supplying or cutting off power to at least one ZigBee power strip 100 and at least one of information processed by the second MCU 204 based on the ZigBee. The second ZigBee communication module 202 wirelessly bidirectionally communicates with the ZigBee power strip 100, and the input unit 206 for inputting a command for selecting a ZigBee power strip 100 or setting a function to the second MCU 204. And a display unit 208 for displaying the command input from the input unit 206 and the data processed by the second MCU 204.

The second MCU 204 outputs a control signal to the at least one ZigBee power strip 100 through the second ZigBee communication module 202, and bidirectionally communicates with the plurality of ZigBee power strips 100 to maintain a state of the ZigBee power strip 100. It is formed to check. At this time, the second MCU 204 processes the data transmitted and received by the second Zigbee communication module 202 and outputs the processed data to the display unit 208. In addition, the second MCU 204 processes the data input from the input unit 206.

The second ZigBee communication module 202 is formed to communicate in both directions with the first ZigBee communication module 104 of the ZigBee power strip 100 supporting the ZigBee communication protocol. At this time. The second Zigbee communication module 202 supplies the control signal to be transmitted and received from the Zigbee power strip 100 to the second MCU (204). In addition, the second Zigbee communication module 202 may be connected to the second MCU 204 to include a function for Zigbee communication, PAN network formation, management, and routing functions.

In addition, the communication method for connecting between the second MCU 106 and the second Zigbee communication module 104 is formed to communicate by SPI, SCI, UART, I2C and the like.

The input unit 206 is formed to input a command to the second MCU 204. Here, the input unit 206 is configured to call the ID of the ZigBee power strip 100 to be controlled or to set a function in the function setting unit 108 of the ZigBee power strip 100. In this case, the input unit 206 may be formed of a keypad or a touch pad.

The display unit 208 is formed to output a value input from the input unit 206 or data processed by the second MCU 204. In this case, the display unit 208 may include a liquid crystal panel, a field emission display panel, a plasma display panel, a light emitting display panel, and the like.

Therefore, the multi-tap control system of the present invention uses the ZigBee multi-tap 100 and the management module 200 based on the ZigBee to more easily and efficiently turn on and off the power of each multi-tap installed in the office or home to safely use electricity. Can save

3 is a diagram illustrating a multi-tap control system according to a second embodiment of the present invention.

Referring to FIG. 3, the multi-tap control system according to the second embodiment of the present invention includes a ZigBee power strip 100 for supplying power to a device using electricity based on a ZigBee communication protocol, and a ZigBee power strip 100 based on the ZigBee communication protocol. And a dual tone multi-frequency (DTMF) decoder 210 to control the management module 200 remotely by accessing the management module 200 and the wired / wireless telephone network 218 to control power by bidirectionally communicating with each other. do.

At this time, the configuration of the Zigbee power strip 100 and the management module 200 according to the second embodiment except for the DTMF decoder 210 which interprets the DTMF signal and supplies it to the second MCU 204 is the same as that of the first embodiment. Since the description thereof is omitted.

The DTMF decoder 210 is formed so that the second MCU 204 can interpret the DTMF signal. Here, when the user connects to the management module 200 through the wired / wireless telephone network 218 using a general telephone or a mobile phone, the DTMF decoder 210 interprets the signal of the DTMF and supplies it to the second MCU 204. In this case, the DTMF decoder 210 may be formed outside the second MCU 204.

4 is a diagram illustrating a multi-tap control system according to a third embodiment of the present invention.

Referring to FIG. 4, a multi-tap control system according to a third embodiment of the present invention bidirectionally communicates with a multi-tap based on a Zigbee multi-tap 100 and a Zigbee communication protocol to supply power to a device using electricity based on a Zigbee communication protocol. It is configured to include a web server PC 212 to control the management module 200 to access the management module 200 and the Internet network 222 to control the power.

At this time, the ZigBee multi-tap 100 and the management module 200 according to the third embodiment can be accessed directly from the user PC 220 through the interface unit 214 and the interface unit 214 connected to the Internet network. Since the configuration except for the configured web server PC 212 is the same configuration as the first embodiment, a description thereof will be omitted.

The interface unit 214 is formed so that the management module 200 and the web server PC 212 can be connected. At this time, the interface unit 214 is connected to the communication port configured in the web server PC 212 so that the information of the management module 200 for the ZigBee multi-tap 100 can be confirmed on the web page of the web server PC 212. Form. Here, the interface unit 214 is formed of a communication port that can be connected to the PC, such as USB, IEEE 1394, RJ-45 port, RJ-19 port, RJ-xx port and the like.

The web server PC 212 is connected to the Internet network 222 is formed to control the management module 200 directly on the user PC (220). At this time, the web server PC 212 is configured with a web page inside the user PC 220 to check the state of the ZigBee multi-tap 100, the control signal transmitted through the Internet network 222 to the interface unit 214 Through the second MCU 204 is formed to be delivered. In addition, a web page configured in the web server PC 212 may be formed in the memory unit 216 inside the second MCU 204 to control the Zigbee power strip 100 as shown in FIG. 5. Can be.

The second MCU 204 is formed to control the Zigbee power strip 100 by receiving a control signal from the web server PC 212. At this time, the second MCU 204 transmits a control signal to the ZigBee power strip 100 to control the control signal transmitted through the interface unit 214 to the web server PC 212 through the second ZigBee communication module 202. Supply.

FIG. 6 illustrates that a multi-tap control system according to the first to third embodiments of the present invention is installed in an office, a factory, or a home.

As described above, Zigbee (IEEE 802.15.4) wireless network is capable of point-to-point networking so that many devices accommodated in one band can communicate with each other at the same level. Accordingly, one management module may turn on or off the plug socket of each ZigBee power strip to which a device using electricity is connected or control power supplied to a plurality of ZigBee power strips.

On the other hand, the present invention described above is not limited to the above-described embodiment and the accompanying drawings, it is possible that various substitutions, modifications and changes within the scope without departing from the technical spirit of the present invention It will be apparent to those skilled in the art.

Multi-tap control system according to an embodiment of the present invention as described above can be easily and efficiently turned on and off the power of the power strip in the office or home to safely use or save electricity.

Claims (19)

A multi-tap control system having at least one ZigBee power strip for supplying power to a device using electricity and a management module for bidirectionally communicating with each of the ZigBee power strips to control the power supply. Each Zigbee multi-tap A plurality of plug sockets connected to the plugs of the electric device; A first MCU in charge of information processing and controlling the plurality of plug sockets according to a signal from the management module; The first MCU is connected to any one of SPI, SCI, UART, and I2C to wirelessly communicate information processed by the first MCU with the management module based on a Zigbee communication protocol, and form and route a PAN network. A first Zigbee module performing a function; A function setting unit for setting a function in each of the plug sockets, and A locking device for driving each of the plug sockets independently; The management module A second MCU for outputting a control signal for supplying or cutting off power to each of the Zigbee power strips; The second MCU is connected to any one of SPI, SCI, UART, and I2C to wirelessly communicate the information processed by the second MCU with each ZigBee multi-tap based on a Zigbee communication protocol, and also form a PAN network formation and routing function. A second Zigbee communication module to perform; An input unit for inputting a command for selecting each ZigBee multi-tap or setting a function to the second MCU; A display unit for displaying a command input from the input unit and data processed by the second MCU; A web control PC configured to directly control the management module through an Internet network after checking a state of the ZigBee multi-tap in a user's PC; And an interface unit configured to connect the management module and the web control PC. delete delete delete The method of claim 1, The control signal supplied to the first MCU in the locking device is a multi-tap control system, characterized in that the priority is assigned to the control signal supplied to each of the plug socket. The method of claim 1, The function setting unit An ID setting unit for setting an ID of each Zigbee multi-tap; A time setting unit for setting a use time of each plug socket; Multi-tap control system characterized in that it comprises an overload detection unit for detecting a load on each of the plug socket. The method of claim 6, The time setting unit And a time setting switch to set a use time of each plug socket. The method of claim 7, wherein The time setting switch is a multi-tap control system, characterized in that it is formed so that it can be set by counting a predetermined time in the first MCU. The method of claim 6, The overload detection unit A notification unit for notifying a user of an overload detected in each of the plug sockets; Multi-tap control system, characterized in that it comprises a main power cut-off unit for shutting off the entire power of the Zigbee power strip. The method of claim 9, The notification unit An alarm member for informing an overload state detected by the overload detector; And a reset switch for resetting the overload state. delete The method of claim 1, The management module And a DTMF decoder connected to a wired / wireless telephone network so as to control the Zigbee multi-tap and capable of interpreting DTMF signals. delete delete delete delete The method of claim 12, And the DTMF decoder is formed inside the second MCU. The method of claim 1, The interface unit is a multi-tap control system, characterized in that consisting of any one of USB, IEEE 1394, RJ-45 port, RJ-19 port, RJ-xx port. The method of claim 1, The web page is The multi-tap control system, characterized in that it further comprises a memory unit to be configured in the second MCU.

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