KR20160058402A - Control system for malfucntioning fluorescent lamp - Google Patents

Abstract

The present invention relates to multi-fluorescent lamp used equipment. A system for detecting a defective fluorescent lamp comprises: a casing in which a fluorescent lamp is mounted; a ballast stabilizer embedded in the casing; a first current sensing unit positioned on a line through which current is supplied from the ballast stabilizer to the fluorescent lamp, and provided to sense current output from the ballast stabilizer; a resistor unit connected to the fluorescent lamp in parallel, at a rear end of the first current sensing unit; a second current sensing unit provided to sense current output by the resistor unit; a management terminal; and a remote management server receiving data on a change in the current from the management terminal to determine whether the fluorescent lamp is defective. According to the present invention, the system for detecting a defective fluorescent lamp may monitor and control a plurality of lighting devices collectively or individually. Furthermore, the system may supply power to the fluorescent lamp through a communications line using a power on LAN (POE) device without a separate power supply line, and two individual current measurement devices may be installed on a ballast stabilizer side as well as the fluorescent lamp to check whether the fluorescent lamp and the ballast stabilizer are defective, thus increasing economic efficiency. The system may send information on the location or defective portion of a fluorescent lamp which is determined as a defective one to a manager in real time by the remote management server, thereby enabling the integrated management of a plurality of facilities.

Description

[0001] The present invention relates to a control system for malfunctioning fluorescent lamp,

The present invention relates to an apparatus for using multiple fluorescent lamps, and more particularly, to an ideal fluorescent lamp detection system that enables remote control of actions such as power shutdown by detecting the presence or absence of a fluorescent lamp.

Smart Home is a term referring to a private home that supports automation. It refers to a house that is constructed to control lighting, temperature, doors, windows, and appliances in a house through a remote network. It is an Internet-based remote management system. When applied to a building, it is referred to as a "smart building" or an intelligent building, and integrates four systems such as architecture, communication, office automation, Functionality, efficiency, comfort, functionality, reliability, and safety. It is a building that integrates office automation for home air conditioning, lighting, electric power system automation, automatic fire detection, security expense, information network function, office efficiency and environment improvement.

This smart system is a system that integrates and manages the power network, communication network, water supply and drainage piping and their control units, which are conventionally constructed and managed in the home or building, based on the IT network. The communication protocol can be embedded.

Power on Ethernet (POE) is a technology to supply power for communication such as a wired / wireless router, hub, or CCTV as well as communication data through a LAN line. It is easy to install the equipment with simple wiring and requires a separate power line. There is an advantage that the maintenance is advantageous because it does not. In addition, when the POE method is applied, remote control is possible by connecting the device to the Internet together with power supply.

There has been no commercialization of the home smart system or the smart building system until now, but it is urgently required to introduce the remote management technology in the facilities requiring the regular management such as the lighting system of the subway and the streetlight control system.

Korean Patent Registration No. 10-0840965 (2008-06-30) discloses an electronic ballast of a high-pressure discharge lamp installed in a support, and more specifically, it acquires power consumption information and status information of an electronic ballast connected to a server and a network So that the electronic ballast can be controlled by the server. To this end, the citing technology includes a power input unit for supplying power input from the outside, an MIL filter for removing noise from a power source applied from the power input unit, a full wave rectifying unit for full-wave rectifying and smoothing a power source through the MIL- An inverter unit for improving the power factor of the power source outputted from the full wave rectifying unit and performing a switching operation so as to apply a square wave power to the high pressure discharge lamp and an electronic ballast including a resonance unit for lighting the high pressure discharge lamp, The electronic ballast eliminates various noise and noise signals generated during the process of converting a commercial voltage to a high voltage from a line connecting the full-wave rectification unit and the inverter unit, and detects a pure current value Current sword A voltage detecting unit connected to the current detecting unit in parallel to remove various noise and noise signals generated during the process of converting a normal commercial voltage to a high voltage and to detect only a pure voltage value, and a high voltage discharge lamp for a predetermined time A calendar and a clock function for managing the off and on times to operate the lamps and the current value and the voltage value information detected from the voltage detector and the current detector to control the brightness of the high pressure discharge lamp, A microprocessor for calculating and storing the amount of electric power used from the lighting time to the light-off time, and transmitting the status information obtained by the microprocessor and the calculated power usage amount information to an external management server according to a control command applied from the management server At the same time, And a current control unit controlling the switching operation of the inverter unit by controlling the driving power applied to the inverter unit by the microprocessor so as to control the switching operation of the inverter unit. A ballast is provided.

The above cited technology enables remote communication and control of the lighting facility, monitors the power consumption, and monitors and controls a plurality of lighting devices using a network connected to the central server.

The above cited technology requires a communication device, a repeater, a microprocessor, and the like for allowing a wired / wireless communication unit built in an illumination facility to wirelessly communicate with a management server, which increases the installation and maintenance cost of the system. In addition, since a separate power supply network separate from the communication network is required, there is a problem that costs for installation of the facility also increase.

In order to solve the above-described problems, the present invention provides a lighting system comprising: a minimum electric circuit for detecting the abnormality of a high-voltage discharge tube such as a fluorescent lamp; And an abnormal fluorescent light detection system connected remotely to the control device to monitor and control a plurality of lighting devices collectively or individually.

In addition, it is possible to supply the fluorescent lamp power through communication line using POE (Power On Ethernet) device without separate power supply line, and two separate current measuring devices are installed in the ballast as well as the fluorescent lamp, An abnormal fluorescent light detection system is provided which can transmit information such as the position of the fluorescent lamp, abnormality area, and the like which are confirmed by the remote management server to the manager in real time.

Other objects of the present invention will become readily apparent from the following description of the embodiments.

According to an aspect of the present invention, there is provided an illumination lamp comprising: a casing provided with a fluorescent lamp; A stabilizer incorporated in the casing; A primary current sensing unit positioned on the line from which the current is supplied from the ballast to the fluorescent lamp, and configured to sense a current output from the ballast; A resistor connected in parallel to the fluorescent lamp at a rear end of the primary current sensing unit; A secondary current sensing unit configured to sense a current output from the resistor unit; A control terminal built in the casing and connected to the primary current sensing unit and the secondary current sensing unit to transmit current change data and having a power switch for supplying or blocking power to the ballast; And a remote management server that receives current change data from the management terminal to determine whether the fluorescent lamp is abnormal, supplies power to the management terminal, and instructs the management terminal to apply or block the power of the fluorescent lamp An ideal fluorescent light detection system is provided.

The management terminal may further include: a digital signal converter for converting analog signals input from the primary current sensing unit and the secondary current sensing unit into digital data; A communication unit provided for data communication with the remote management server; A POE (Power On Ethernet) splitter for extracting power supplied from a communication line to be connected to the remote management server; A power switch provided to supply or cut off power supplied from the POE splitter module to the ballast; And a control unit configured to control operations of the communication module and the power switch.

Wherein the remote management server comprises: a POE injector configured to supply power and data to a communication line connected to the management terminal; A network switch unit connected to the POE injector module by a communication line; A management database connected to the network switch module and storing data transmitted from the management terminal; An abnormality determination unit configured to determine whether each management terminal is abnormal from the management database; A countermeasure section arranged to take action on the management terminal module judged as an abnormal state from the abnormality determination module; And a central control unit adapted to control the management database, the abnormality determination module, and the action module.

Wherein the resistance unit has a resistance value higher than a resistance value of the fluorescent lamp.

According to the present invention, there is provided an abnormal fluorescent light sensing apparatus comprising: a minimum electric circuit for detecting the presence or absence of abnormality in a high-pressure discharge tube such as a fluorescent lamp; a control unit for transmitting an abnormal signal derived from the electric circuit, And a plurality of lighting apparatuses, which are remotely connected to the control apparatus, can be collectively or individually monitored and controlled.

In addition, it is possible to supply the fluorescent lamp power through the communication line using POE (Power On Lan) device without separate power supply line, and two separate current measuring devices are installed in the ballast as well as the fluorescent lamp, It is economical because it can check.

It is possible to transmit the information such as the position of the fluorescent lamp which has been confirmed by the remote management server and the abnormal area to the manager in real time, thus enabling the integrated management of a plurality of facilities at the remote place.

FIG. 1 is a block diagram showing an embodiment of an ideal fluorescent light detection system according to the present invention.
FIG. 2 is a block diagram showing an embodiment of a management terminal of an abnormal fluorescent light detection system according to the present invention.
3 is a block diagram showing an embodiment of a remote management service of the ideal fluorescent light detection system according to the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but is to be understood to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention, And the scope of the present invention is not limited to the following examples.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like or corresponding elements are denoted by the same reference numerals, and redundant explanations thereof will be omitted.

FIG. 1 is a block diagram showing an embodiment of an ideal fluorescent light detection system according to the present invention, and FIG. 2 is a configuration diagram showing an embodiment of a management terminal of an ideal fluorescent light detection system according to the present invention.

Referring to FIGS. 1 and 2, the present invention may include an illumination lamp 100, a management terminal 160, and a remote management server 200.

The illumination lamp 100 is a dimming facility in which a general fluorescent lamp is replaceably installed, and a plurality of lamps can be installed in a ceiling surface to be provided in a public facility such as a subway where dimming should always be performed.

Although not shown in the drawings, a casing (not shown) provided to serve as an enclosure of the illumination lamp 100 may be provided in the form of a general fluorescent lamp casing, and the stabilizer 120, the management terminal 160, Respectively.

The ballast 120 applies a high voltage kick voltage so that the electrodes of the fluorescent lamp 110 are discharged and supplies a current to prevent the overcurrent from flowing after mercury or argon gas in the fluorescent lamp 110 is charged It plays a role of controlling properly. In general, the ballast is a starter type, a rapid start type, an instant start type, and an electronic ballast. The ballast according to the present invention may be any one of a starter type, a rapid start type, an instant start type, or an electronic type.

The primary current sensing unit 130 is connected to the rear end of the ballast 120 in the circuit for lighting the fluorescent lamp 110 to detect a change in the amount of current derived from the ballast 120 and transmit the sensed change to the management terminal 160 do.

Referring to FIG. 1, the primary current sensing unit 130 is shown connected in series to the rear end of the ballast 120, but this is for the sake of simplicity of illustration. Actually, as in a general current meter, And are arranged to be connected in parallel.

The current value measured by the primary current sensing unit 130 is converted into analog data and transmitted to the management terminal 160 through the measurement line 100b. The analog data transmitted from the primary current sensing unit 130 is transmitted to the remote server 200 through the management terminal 160.

The resistance unit 140 is connected in parallel with the fluorescent lamp 110 and the secondary current sensing unit 150 is connected to the rear end thereof. The amount of current flowing through the resistance portion 140 changes as follows when the amount of current when the fluorescent lamp 110 normally operates is defined as i ₀ and the amount of current at the time of failure is defined as i _t .

i ₀ < i _t

The secondary current sensing unit 150 measures the changed amount of current and converts it into an analog signal and transmits it to the management terminal 160 through the measurement line 100b. The management terminal 160 converts the measurement value of the secondary current sensing unit 150 into a digital signal and transmits the digital signal to the remote management server 200 through the Internet 400. The remote management server 200 transmits the measurement After comparing the value (i _t ) with the current value (i ₀ ) during normal operation, the abnormal state is judged and the follow-up action is executed.

At this time, since the resistance value of the resistance unit 140 is set to be higher than the load resistance value of the fluorescent lamp 110, more current flows to the line on the fluorescent lamp 110 side during normal operation and when the fluorescent lamp 110 is broken More current flows through the line on the side of the resistor section 140, so that the current measurement value of the secondary current sensing section 150 side can be changed.

Accordingly, the resistance value P _B of the resistance portion 140 is set to satisfy the following inequality with respect to the resistance value P _A of the fluorescent lamp 110.

_A P <P _B

2, the management terminal 160 may include a digital signal conversion unit 161, a communication unit 162, a POE splitter 163, a power switch 164, and a control unit 165.

The digital signal converting unit 161 converts the analog signals transmitted from the primary current sensing unit 130 to the secondary current sensing unit 150 into a digital signal that can be transmitted to the Internet.

The communication unit 162 may be provided with an embedded LAN card module that allows the remote management server 200 and the management terminal 160 to communicate with each other.

The POE splitter 163 separates the power source supplied through the LAN line from the data signal and supplies the power source to the ballast 120 through the power switch 164. POE (Power On Ethernet) is a technology to supply a power source for operation of terminal equipment as well as data through a RJ45 cable of a LAN standard, and can supply a current of 30W.

The POE splitter 163 allows the management terminal 160 and the ballast 120 to be powered by receiving power through a communication line without a separate power supply line, Can be facilitated. Accordingly, the POE splitter 163 separates the power source from the communication line drawn into the management terminal 160 and supplies the power source to the ballast 120 through the power line 100a.

The power switch 164 is provided to turn on / off the power supplied to the ballast 120 by the controller 165. The power switch 164 may be provided as a separate manual operation button. However, in the present invention, the power switch 164 is provided in a manner such that it is built in the management terminal 160 and operated by the control unit 165.

The control unit 165 transmits data on the abnormality of the fluorescent lamp 110 to the remote management server 200 via the communication unit 162 and operates the power switch 164 according to the action of the remote management server 200 And serves to apply or cut off the power supplied to the ballast 120. [

3, the remote management server 200 includes a POE injector unit 210, a network switch 220, a management database 230, an abnormality determination unit 240, an action unit 250, and a central control unit 260, &Lt; / RTI &gt;

The POE injector unit 210 is provided to supply power to a communication line connected to the management terminal 160. The remote management server 200 according to the present invention is connected to a network composed of a plurality of management terminals 160 so that the POE injector unit 210 can be integrated into the network switch 220.

The network switch 220 serves to allow the server 200 to identify the individual management terminal 160 by assigning a unique IP address to each management terminal 160.

The management database 230 classifies and stores the current value data transmitted from each management terminal 160 so that the abnormality determiner 240 can determine whether or not the current value is abnormal according to the variation of the current value.

The abnormality determination unit 240 compares the current change value and determines that the fluorescent lamp is malfunctioning when the current value increases and the current value passed through the resistance unit 140 is inputted and transmits the determination result to the central control unit 260 .

The central control unit 260 transmits the IP address and the fault state of the corresponding fluorescent lamp to the action unit 250, and the action unit 250 transmits text to the manager in real time or displays an alarm on the monitor. The central control unit 260 instructs the control unit 165 of the management terminal 160 to shut off the power switch 164 or to allow the POE injector unit 210 to cut off power supplied to the management terminal 160 The power supply to the faulty fluorescent lamp can be stopped by the command.

The operation of the abnormal fluorescent light detection system according to the present invention will now be described.

According to the present invention, the remote management server 200 assigns an IP address to each of a plurality of illumination lights 100 in which the management terminal 160 is embedded, and controls the remote management server 200 through the Internet to quickly turn off a faulty fluorescent lamp, Notification and monitoring of fault conditions, etc., thereby minimizing the number of management personnel for multiple lighting facilities.

In addition, based on POE (Power on Ethernet) device, it is possible to supply power for fluorescent lighting and management terminal (160) operation without additional power line construction besides construction of communication line, , It is possible to reduce the construction cost when constructing a new facility, to facilitate maintenance, and to enhance the efficiency of power management.

Although the present invention has been described with reference to the accompanying drawings, it is to be understood that various changes and modifications may be made without departing from the spirit of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the following claims.

100: Lighting light
110: Fluorescent lamp 120: Ballast
130: primary current sensing unit 140:
150: secondary current sensing unit 160: management terminal
161: Digital Signal Conversion Unit 162:
163: POE splitter 164: Power switch
165: controller 200: remote management server
210: POE injector 220: network switch
230: management database 240: abnormal judgment unit
250: Action section 260: Central control section

Claims (4)

In the illumination lamp,
A casing provided with a fluorescent lamp;
A stabilizer incorporated in the casing;
A primary current sensing unit positioned on the line from which the current is supplied from the ballast to the fluorescent lamp, and configured to sense a current output from the ballast;
A resistor connected in parallel to the fluorescent lamp at a rear end of the primary current sensing unit;
A secondary current sensing unit configured to sense a current output from the resistor unit;
A control terminal built in the casing and connected to the primary current sensing unit and the secondary current sensing unit to transmit current change data and having a power switch for supplying or blocking power to the ballast; And
And a remote management server that receives current change data from the management terminal to determine whether the fluorescent lamp is abnormal, supplies power to the management terminal, and instructs the management terminal to turn on or off the power of the fluorescent lamp Fluorescent light detection system. The method according to claim 1,
The management terminal,
A digital signal conversion unit for converting an analog signal input from the primary current sensing unit and the secondary current sensing unit into digital data;
A communication unit provided for data communication with the remote management server;
A POE (Power On Ethernet) splitter for extracting power supplied from a communication line to be connected to the remote management server;
A power switch provided to supply or cut off power supplied from the POE splitter module to the ballast; And
And a controller configured to control operations of the communication module and the power switch. The method according to claim 1 or 2,
The remote management server comprises:
A POE injector provided to supply power and data to the communication line connected to the management terminal;
A network switch unit connected to the POE injector module by a communication line;
A management database connected to the network switch module and storing data transmitted from the management terminal;
An abnormality determination unit configured to determine whether each management terminal is abnormal from the management database;
A countermeasure section arranged to take action on the management terminal module judged as an abnormal state from the abnormality determination module;
And a central control unit configured to control the management database, the abnormality determination module, and the action module. The method according to claim 1,
Wherein the resistance portion comprises:
And the resistance value P _B of the resistance portion is made to satisfy the following inequality with respect to the resistance value P _A of the fluorescent lamp.
_A P <P _B

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