KR100490951B1 - Apparatus and method for control of GPS signal receivable and telecommunicatable street lamp - Google Patents

Abstract

The present invention relates to a GPS signal reception and telecommunication streetlight management device and a management method using the streetlight management device, the present invention relates to the location and lighting of the streetlights and security lights and outdoor lighting for similar purposes, and to monitor the current status and troubleshoot · It is characterized by GPS signal reception and telecommunication street light management device which enables remote control of failure management and history management and street light management method using the street light management device.

Description

GPS signal reception and telecommunication street light management device and street light management method using the street light management device {Apparatus and method for control of GPS signal receivable and telecommunicatable street lamp}

The present invention relates to a GPS signal reception and telecommunication streetlight management device and a management method using the streetlight management device, and more specifically, the location and lighting and the current status monitoring and failure of streetlights and security lights and outdoor lighting for similar purposes The present invention relates to a GPS signal reception and telecommunication street light management device capable of remotely controlling processing, fault management, and history management, and a street light management method using the street light management device.

Conventionally, since a system for managing a street lamp is simply configured in terms of a blinking function, there is a problem of causing danger or wasting power by supplying power to a broken street light without recognizing it even if the street lamp malfunctions or malfunctions. In addition, there have been simple attempts to automate the turning on and off of street lamps, to correct the present time, or to send signals to forcibly keep the lights on.

In general, GPS signal reception has a fundamental error factor that is not recognized temporarily or is recognized as an error code during continuous communication due to errors caused by external electrical influences because it is communicated in outdoor use conditions with many electrical climate obstacles. In general, in the satellite signal reception streetlight control attempted by prioritizing only the function, the error of visual information is used without verifying the error, thereby impeding the normal system operation and causing the streetlight to malfunction.

Until now, in the method of recognizing the location of the street lamp, the list was managed by artificially searching for the street lamp, creating a status table, and displaying it on the street lamp. Whenever it occurred or grasped the situation, it had to be visited.

In order to check and repair the faults at the site where the street lamps are installed, the process of finding out the installation information and the fault information and managing the maintenance history so far depends on man-made work. It acted as a cause of deterioration.

When the number of street lamps is small, it is not difficult to manage the street lamps and check the status by personnel, but when the number of street lamps is large and the installation area is large, it causes various problems such as an increase in the human and time management burden required for management.

The object of the present invention as devised in view of these conventional problems, firstly, to monitor the operating state of the street lamp and take a safe operation such as power saving in the event of a failure to prevent power wastage, by detecting daylight (날씨 光) changes the weather To compensate for the ambient brightness caused by all-weather streetlights,

Secondly, as a means of displaying the fault and management status through the LED without the need to operate a separate device or through remote communication, the management status of the street light can be immediately determined at a short distance. By correcting to reduce the position error and increase the accuracy, it is possible to recognize the exact position and to clearly distinguish the adjacent street light,

Third, the system is installed in the field together with the street light without any special setting. When the power is supplied, the system automatically recognizes the location and the correct current time from the GPS receiver. It can be easy to manage and remotely manage a number of street lights to achieve convenient and quick management, and by configuring a two-way remote communication unit for short-range and long-distance use as a remote management device and a portable management device Can communicate smoothly with the central management means that are configured,

Fourthly, it detects the operation of the street lamp, calculates the malfunction information such as malfunction or flickering, and cuts off the power supplied to the street lamp through the street lamp driver to prevent waste of power and safely handle the street lamp. When configured through a single or branched circuit, the fault analysis analyzes the current and the current of the circuit based on the information received from the streetlight fault handling device and compares them with each other. You can compare states,

Fifth, it calculates the fault by analyzing the signal of the street light condition monitoring unit, and stores the fault information in the memory means for each date of the system, and can later look up the fault contents stored in the memory means, and transmits remotely through the two-way remote communication unit, When a request is made from the communication unit, the fault information stored in the memory means by date can be transmitted to the bidirectional remote communication unit to check the fault information remotely.

Sixth, the history of the street lamp is input to the system by storing the installation information of the street lamp, the parts replacement information, the troubleshooting information and the failure information calculated by the system in the memory means by the date of the system clock operated by the control computer. The system can check the history when necessary, and also finds the management area of the street lamp by using the latitude information received from the GPS receiver as a variable of the program that calculates the citizen's fat time, and checks the point by itself according to the current time analyzed from the GPS information. It is to provide a street lamp management system and a street lamp management method that can be easily turned on and off by calculating the light off time.

An object of the present invention described above is a control computer for embedding and driving the operating program of the system; A GPS receiver for providing location information and visual information to a control computer; A remote communication unit configured to be connected with the control computer to bi-directionally communicate information through wireless communication; An RCT that drives the clock and operates the current time and date; An input / output unit connected to a control computer to input a signal and display operation information; A streetlight driver for controlling power supplied to the streetlight by a signal of a control computer; A daylight detecting unit connected to the control computer for detecting an external brightness signal and converting the brightness signal into a digital signal and providing the same to the control computer; A circuit current sensing unit for sensing an energizing current of the street light power circuit and providing the control computer to the control computer; A power supply unit supplying an operating power required for each system unit; A streetlight management apparatus using a telecommunication and GPS receiving streetlight management device, comprising: memory means for storing and managing operating conditions, fault information, and history information of a street light; An ID unit connected to the control computer to give an individual identification number; Microcomputer that operates the trouble-shooting program, a status detector that detects the operation status of the streetlight and converts it into an input signal of the microcomputer, a fault-handling unit that opens and closes the streetlight path according to the microcomputer's signal, and troubleshoots the streetlight path. PLC communication unit for transmitting signals, power unit for supplying power to the system by the power supplied to the street lamp, ID unit for individual classification recognition, setting unit for setting the fault analysis and processing standards, and display unit for displaying the status of fault processing A fault handling apparatus for detecting an operation state of a street light, analyzing a failure by itself, displaying a processing state, and transmitting the processing state to the outside through a PLC communication unit; A PLC communication unit connected to the control computer and communicating with a signal transmitted from the failure processing apparatus; It is achieved by a street lamp management device characterized in that it manages the operation status and failure handling status of the street lamp, including, the street lamp management method of the street lamp management device is a management method for managing a street lamp or security lamp and similar outdoor electrical facilities, etc. In the first step of receiving an external power source to convert the noise and surge to a stable state to supply to each part of the system; A second step in which the control computer initializes the system, recognizes each part of the system, loads an operating program for operating the recognized system, accesses the date and current time from the RTC, and accesses an individual unique number from the ID part to start operation Process; A third step of the control computer which has started the operation as described above, recognizing the program variable from the memory means at which the initial value is set; A fourth step of accessing the time information from the GPS receiver and correcting the time information compensated for the error analysis process and the delay time to the current time of the RTC; A fifth step of accessing the location information from the GPS receiver and storing the location information of the latitude and longitude analyzed through error analysis and error correction in a memory means; A sixth step of receiving the operating condition and history information from the bidirectional telecommunication unit and updating the memory means; The seventh step of calculating the citizen's fatal time using the date of the system calculated in the fourth step and the latitude information stored in the memory means in the fifth step, and correcting the difference in longitude and local conditions, and calculating the standard point / off time. and; An eighth step of calculating an operation signal for each output circuit by driving a street lamp operation program using the current time compensated in the fourth process, the standard point / light off time calculated in the seventh process, and the operating conditions stored in the memory means in the sixth process; Process; A ninth step of controlling operation of the street lamp for each circuit by sending the operation signal calculated in the eighth step to the street lamp driving means; It monitors the operation status of the street lamp through the status monitoring means and judges the failure by comparing with the set condition, and if the failure is output, it displays to the outside. A tenth step of uploading; An eleventh step of transmitting the circuit break signal of the street light to the control computer through the PLC communication means and storing the cutoff state as a history in the memory means for each time and date of the system; Recognizes the power circuit current supplied to the street lamp, converts it into a digital signal, sends it to the control computer, sets the lighting recognition current range of the upper and lower limits of lighting according to the type and capacity of the street lamp, and the sampling cycle and cumulative degree of the received signal. By setting the sampling number to adjust the sensitivity by averaging the number, to prevent the sudden change of the signal, to determine the failure according to the above means, to delay the time required for the lighting step and to output, and through the streetlight driver according to the failure signal A twelfth step of handling a failure of the street light by shutting off power supplied to the street light; When the operation status of the street lamp is transmitted through the remote communication means at each event and the information request code is received from the remote communication unit, ID and location information, operation status, program operation information, installation / maintenance items, and trouble shooting records It is implemented by a street lamp management method characterized in that the street lamp is managed through a thirteenth process of transmitting history information.

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Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram showing the configuration of a street lamp management device according to the present invention. According to the present invention, a remote communication unit 420 capable of exchanging information through wireless communication is provided in a control computer 410 in which an operating program of a system is embedded and driven. ) And a commercial GPS receiver 210 are configured to be connected, and the central remote management server 100 of the central control center that embeds and drives the operating program of the system is configured to communicate with the remote communication unit 420 remotely. The GPS receiver 210 which provides location information and visual information to the system is connected and installed.

On the other hand, the control computer 410 drives the clock and operates the current time and date RTC 470 and the memory means 440 for storing and managing the operating conditions, failure information and history information of the street lamp and input and operation of the signal An input / output unit 450 for displaying information and a power supply unit 480 for controlling the street lamp 300 by controlling power by a signal of the control computer 410, and a power supply unit 600 for supplying operating power to each of the systems; , The fault handling device 500 for identifying the operating state of the street light and handling the fault is composed of the control computer 410 and the PLC communication unit 541 which communicates the fault handling signal through the street light path through the organic connection. have.

It is also possible to connect and configure the portable remote management device 110 capable of exchanging information with the remote communication unit 420 through wireless communication and controlling a street light, and when there is an abnormality in the power supply unit 600, The preliminary power supply unit 610 is further connected to supply the light source, and further includes a daylight detecting means 460 for detecting an external brightness and providing a detected signal, and an ID unit 430 for assigning an individual identification number. You can also use the connection configuration.

The operating state of the present invention having the structure as described above is initialized to start the operation when the commercial power is supplied to the system from the power supply unit 600, as shown in Figure 1 and 11 attached to the preliminary power supply unit 610 Charge and monitor the supply of commercial power.

When the commercial power is cut off, the reserve power is continuously supplied so that the power supply of the system is not cut off, and the operation is continued so that the operation of the system does not stop for a predetermined time. If the predetermined time is continued for more than a predetermined time, the electrostatic lock is stored in the EEPROM 440 according to the date and time of the system, sent out through the telecommunications unit, the processing of the system is completed by the reserve power, and the system is safely shut down.

On the other hand, when the system starts operating, it recognizes the system, accesses the RTC 470, and accesses the driving parameters from the EEPROM 440 that recognizes the unique number. In addition, GPS information is received from the GPS signal transmitting apparatus 200 through the GPS receiver 210, and two consecutive coordinates are divided and extracted into components by latitude and longitude. Obtain and accumulate.

The accumulation process is repeated a predetermined number of times, cumulatively summed, the distribution is obtained, the error is reduced, the corrected coordinates are calculated, and the calculated coordinates are stored in the EEPROM 440. Determining GPS information from the received signal by waiting for external signal reception, and when GPS information is received, extracts two sample time information, compares the relative time difference and sampling delay time, analyzes the error and determines the error. The current time is calculated by compensating the delay time in one sample time information, and the RTC 470 is corrected by the calculated current time.

The latitude coordinates are retrieved from the EEPROM 440, the date is retrieved from the RTC 470, and the citizen's bedtime time calculation program is driven to calculate the citizen's bedtime time in the morning and evening. The civil civic clearing time calculated above is corrected according to the correction time parameter of the EEPROM 440, and is calculated as a point-off time. Drives the street lamp driver according to the calculated dot / light off time and the operating conditions for each circuit set in the EEPROM 440, and supplies power to the street lamp 300 through the street lamp driver 480 and returns to wait for reception of an external signal. .

When power is supplied to the street lamp 300, the fault handling apparatus 500 detects an operating state of lighting of the street lamp 300, determines a failure according to a set criterion, and when a failure signal is calculated, power is supplied to the failure handling unit 530. While the power is interrupted, the street lamp 300 is safely handled, the fault handling result is displayed, and the processing result is transmitted through the PLC communication unit 540.

The control computer 410 receives the failure processing result through the PLC communication unit 541 and updates and stores the processing information in the EEPROM 440 for each ID. The fault handling state for each ID of the fault handling unit 440 is displayed through the input / output unit 450, and the fault handling information is transmitted through the remote communication unit 420 together with the position coordinates, the ID, and the real time.

Communication with a plurality of street light management device of the present inventors at a remote site, the central remote management device for managing the street light 300, that is, through the central remote management server 100 to check the contents of the fault handling along with the position coordinates and ID and real time.

If the GPS time information is determined to be an error, the system is operated according to the current time of the RTC 430, and a citizen driving time calculation program driving process is executed.

When the external signal is a remote code, the data code and the request code are determined, and if the request code is transmitted, the operation status, current time, operation condition, history information, and troubleshooting information are transmitted through the remote communication unit together with the position coordinates, ID, and real time.

If the remote communication code is a data code, the operation condition and history information are received from the remote communication unit 410, and the received remote signal is updated and stored in the EEPROM 440.

The street lamp management method of the street lamp management device of the present invention, which is constructed and configured as described above, comprises: a first process of supplying to each system by converting power into a stable state by receiving a commercial external power source and filtering noise and surge; The control computer initializes the system, recognizes each part of the system of the control computer, loads the operating program for operating the recognized system, accesses the date and current time from the RTC means, and accesses the individual identification number from the ID unit to start operation. 2 course; A third step of the control computer which has started the operation as described above, recognizing the program variable from the memory means having the initial value set; A fourth step of accessing the time information from the GPS receiver and correcting the time information compensated for the error analysis process and the delay time to the current time of the RTC; A fifth step of accessing the location information from the GPS receiver and storing the location information of the latitude and longitude analyzed through error analysis and error correction in a memory means; A sixth step of receiving the operating condition and history information from the bidirectional telecommunication unit and updating the memory means; The seventh step of calculating the citizen's fatal time using the date of the system calculated in the fourth step and the latitude information stored in the memory means in the fifth step, and correcting the difference in longitude and local conditions, and calculating the standard point / off time. and; An eighth step of calculating an operation signal for each output circuit by driving a street lamp operation program using the current time compensated in the fourth process, the standard point / light off time calculated in the seventh process, and the operating conditions stored in the memory means in the sixth process; Process; A ninth step of controlling operation of the street lamp for each circuit by sending the operation signal calculated in the eighth step to the street lamp driving means; It monitors the operation status of the street lamp through the status sensing means and judges the failure by comparing with the set condition, and if the failure is output, it displays to the outside, and cuts off the street lamp circuit and converts the circuit break state with the ID. Uploading (up-loading) the street light management apparatus; An eleventh step of transmitting a signal to the control circuit of the street lamp to the control computer through the PLC communication means of the street light management device and storing the blocking state as a history in the memory means for each time and date of the system; Recognizes the power circuit current supplied to the street lamp, converts it into a digital signal, sends it to the control computer, sets the lighting recognition current range of the upper and lower limits of lighting according to the type and capacity of the street lamp, and the sampling cycle and cumulative degree of the received signal. By setting the sampling number to adjust the sensitivity by averaging the number, to prevent the sudden change of the signal, to determine the failure according to the above means, to delay the time required for the lighting step and to output, and through the streetlight driver according to the failure signal A twelfth process of processing the failure of the street light by cutting off the power supplied to the street light and displaying it to the outside through the input / output unit; When the operation status of the street lamp is transmitted through the remote communication means at each event and the information request code is received from the remote communication unit, ID and location information, operation status, program operation information, installation / maintenance items, and trouble shooting records A thirteenth step of transmitting history information; A fourteenth step of managing the street light using the main light signal; When the commercial power is cut off, the reserve power is supplied to operate the system for a predetermined time so that the street lamp can be managed through the fifteenth process of safely shutting down.

In order to explain the present invention which operates in the above-described structure in more detail, the current time correction function, the position information calculation function of the street lamp, the fault handling function of the street lamp, the history management function, the function of obtaining the point / light off time, the operation information and the history When the description is divided into the function of changing the setting information, the function of managing the street lamp using the daylight signal, the safety termination function element, etc., the power supply unit 600 is supplied with a commercial external power to filter out noise and surge and to maintain a stable state. The first process of converting power and supplying to each part of the system and the control computer 410 initializes the system, recognizes each part of the system, loads an operating program for operating the recognized system, and accesses the date and current time from the RTC 470. And a second process of starting the operation by accessing the individual unique number from the ID unit 430 and the control which started the operation as described above. Computer 410 and then performing a third step of recognizing the program variables from the EEPROM (440), the initial value set is currently performing a time correction function.

The current time correction function corresponds to the fourth process of the street lamp management method, as shown in FIG. 2A, a control computer 410 for analyzing and processing errors in a system operating program and time information and correcting the current time; The GPS receiver 210, the RTC 470 coupled with the electrostatic compensation rechargeable battery 471, and the input / output unit 450, which receive visual information and provide the system, operate organically with each other.

The operation of the current time correction function is shown in the accompanying drawings, as shown in FIGS. 1 and 2B. First, the control computer 410 accesses the GPS information from the GPS receiver 210 to determine whether the GPS time information is received, and the GPS time information. Is received, successively receives two time information, calculates a relative time difference, compares with the received elapsed time, and determines whether the time difference and the elapsed time are the same, and if the time difference and the elapsed time are the same, the delay time is based on the received time information later. Compensation is calculated at the current time, the RTC 430 is corrected, and the error elapsed time count is reset and returned.

On the other hand, if the time difference and the elapsed time is different, the received time information is discarded and the error time is counted and returned to the initial state. If the accumulated error time exceeds a predetermined time, it is indicated as a GPS information error. If the GPS information is not received in the step of determining whether to receive the GPS information, the error time is counted, and when the error time exceeds the predetermined time, it is displayed as a GPS information error.

The GPS receiver 210 acting as described above may be generally used as a satellite GPS receiver 210 that directly receives a GPS signal from the GPS signal transmitter 200, but the external visual signal is periodically provided by a cellular phone communication network. Receive information may be used for radio time information.

When the bidirectional remote communication unit 541 is configured as a portable communication means, the portable communication means may be provided with visual information for providing GPS information, and at this time, the GPS receiver 210 is not configured separately. It is possible to configure a two-way remote communication unit combined with a GPS receiver that also serves as a two-way remote communication unit and a GPS receiver 210.

On the other hand, the position information calculation function of the street lamp of the street lamp management method is a control computer 410 for analyzing the error and correct the error of the system operating program and the location information, as shown in Figure 3a, and receives the location information from the outside Display unit of the GPS receiver 210, the EEPROM 440 for recording the calculated position information, the remote communication unit 420, the input / output unit 450 for displaying the operation state and the error, and the power supply unit 600 will work organically with each other.

The operation of the position information calculation function of the street lamp corresponds to the fifth process of the street lamp management method. As shown in FIGS. 1 and 3B, when operating power is supplied to each unit through the power unit 600, a control computer ( 410 drives the system and starts operation, and the system accesses the GPS information from the general GPS receiver 210 to determine whether the GPS location information is received, and when the GPS location information is received, two systems are sequentially connected according to the signal period. Receive the location information, classify it into latitude and longitude components, calculate the relative position difference, and compare the tolerance range and size.

If the relative position difference does not exceed the tolerance size, the two position information are divided by component to calculate the midpoint, stored by component, and the error count is reset. By repeating the above process, the distribution of the calculated midpoints is cumulatively summed for each component and the frequency is counted.

If the counted frequency exceeds a predetermined number of times, new coordinates are obtained by averaging the distribution of the sum of the weighted components for each component by the frequency. The position coordinates generated as described above are stored in the EEPROM 440. Using the location information to calculate the street light point, lights out time of the area to operate the street light, to display the location information, and to transmit the coordinates through the remote communication unit 420 and to check the location of the street lamp through the remote management device.

On the other hand, if the position error exceeds the tolerance, the error data is discarded and the number of errors is counted. If the number of errors exceeds a predetermined number of times, the GPS error is recorded in the EEPROM 440, displayed on the input / output unit 450, and returned to access GPS information and extract location information.

On the other hand, if the GPS information is not received, the elapsed time is counted and compared with the predetermined time, the GPS information error is recorded in the EEPROM 440, and returned to access the GPS information and extract the location information.

    The fault handling function of the street lamp of the street lamp management method corresponds to the tenth process of the street lamp management method. As shown in FIG. 4A, the microcomputer 510 for driving the system and operating the failure handling program, the operation of the street lamp State detection unit 520 for detecting the state and converting the input signal of the microcomputer 510, the fault processing unit 530 for opening and closing the path of the street lamp in accordance with the signal of the microcomputer 510, the fault processing through the street light path PLC communication unit 540 for transmitting a signal, a power supply unit 550 for supplying power to the system with power supplied to a street light, an ID unit 560 for individual classification recognition, and a setting unit for setting fault analysis and processing criteria 570 ), A display unit 580 for displaying a fault handling state is provided to form a streetlight failure processing apparatus 500 to operate organically with each other.

Operation of the fault handling function of the street lamp is as shown in the accompanying drawings, Figures 1 and 4b when the street lamp management function supplies power to the street lamp circuit through the street lamp driver 480 according to the lighting conditions, a plurality of combinations for each street lamp at the same time The power is supplied to the fault handling apparatus 500 and initialized to restore the street light power supply circuit to the energized state through the fault handling apparatus 500. The setting value of the setting unit is called according to the type of the street lamp, and the state sensing unit 520 is loaded. It detects the operation state of the street lamp through and sends the converted state signal to the microcomputer (510).

Delay the time it takes to start the discharge lamp until it reaches a complete discharge state, analyze the fault condition by comparing with the set value, and maintain the same state for a predetermined time or more to prevent the microcomputer 510 from malfunctioning due to a momentary change. When calculating the fault signal through the calculation process to recognize as a fault, the power supply to the street lamp is cut off through the fault processing unit 530 to prevent the street lamp from flickering or consuming unnecessary power from the ballast, and safely processed from electrical hazards. In addition, the fault handling result is displayed to the outside through the display unit, and the fault handling information is transmitted to the power line along with the ID through the PLC communication unit 540.

The control computer 210 of the street lamp management function connected to the street lamp power line allows the PLC communication unit 541 to recognize the fault handling information together with the ID.

The state detecting unit 520 is composed of a current sensing means for detecting the operation of the street lamp 300 or light sensing means for detecting the light of the bulb, the sensing unit 520 for detecting the operation state of the street lamp 300 is a street light Recognizing and converting the current supplied to the 300 is converted into a digital signal and sent to the microcomputer 510 and set the lighting recognition current range of the upper and lower limits of the lighting according to the type and capacity of the street lamp 300 and the lighting step Determining by delaying the time required, and by setting the sampling rate to adjust the sensitivity by averaging the sampling cycle and the cumulative frequency of the received signal, and analyze the normal operation and failure by preventing the sudden change of the signal. When the state detecting unit 520 is configured as a light detecting means, the state detecting unit 520 detecting the operating state of the street light 300 can receive only the light emitted by the street light 300 and converts it into a digital signal. Rapid change in the signal by setting the brightness discrimination criteria sent to the microcomputer 510 and recognized as light and recognized as extinction, and setting the sampling rate to adjust the sensitivity by averaging the sampling cycle and the cumulative frequency of the received signal. To prevent.

The fault management function of the street lamp of the street lamp management method corresponds to the twelfth process of the street lamp management method. As shown in FIG. 5A, the system is operated, the street lamp driver 480 is operated, and the fault handling signal is managed. The control computer 410, the remote communication unit 420 for transmitting the operating state of the system to the remote device, the EEPROM 440 for recording the fault handling state, the ID unit 430 for individual identification of the system, display the operating state Input / output unit 450, a circuit current detection unit 490 for detecting current in an output circuit and converting it into a digital signal, a streetlight driver 480 for opening and closing a path of a street lamp, and a power supply unit 600 for supplying operating power to each other. It is organically connected and works.

The operation of the fault management function of the street light is sensed, converted, and transmitted to the control computer 410 through the circuit current sensing unit 490 as shown in the accompanying drawings, FIGS. 1 and 5B. The current value recognized by the control computer is displayed through the input / output unit 450 and transmitted through the remote communication unit. In addition, the control computer 410 detects the number of lit street lights connected to the circuit from the processing signal accessed from the fault handling function, calculates the summed consumption current, and compares the summed current with a preset current value with the recognized current. The fault is determined, and when the fault signal is calculated, the streetlight driving signal is interrupted to cut off the electricity supply to the streetlight circuit through the streetlight driver 480. The calculated fault signal and the fault handling signal of the fault handling apparatus 500 are stored in the EEPROM 440 and displayed externally through an input / output unit 450 such as an LCD and an LED, and transmitted through the remote communication unit 420. The fault management information should be recognized by the remote management device.

The history management function of the street lamp management method corresponds to the fifth process of the street lamp management method, as shown in FIG. 6A, a control computer 410 for driving an operation program and a history management program, and external location information. GPS receiver 210 for providing visual information to the system, remote communication unit 420 for receiving and remotely transmitting history information from the outside, RTC 470 for driving the current time, and EEPROM 440 for storing history information. ), A circuit current detection unit 490 for detecting an operating state of the street lamp 300, and the power supply unit 600 are organically connected to each other to operate.

The operation of the history management function is as shown in Figure 1 and 6b of the accompanying drawings, when the power is supplied from the power supply unit 600 to drive the system and access the GPS information from the GPS receiver 210, the error of visual information and location information Analyze the error and determine the error of GPS information, if the GPS information is an error, output the GPS information error, calculate the current time with the extracted time information, correct the RTC (430), extract the location information and extract the location error And correct the error by analyzing the frequency distribution to calculate the correct position coordinates and store in the EEPROM (440), and receives the installation information and maintenance information of the street lamp along with the history code from the remote communication unit 420 as history information and failure Receive processing information, GPS error, received history information and failure handling information is stored in the EEPROM 440 along with the RTC 430 to manage the history information in the system itself.

When the history information request code is received from the remote communication unit 420, the time information of the RTC 430, the operation information of the system, the history information of the EEPROM 440, the failure management information, and the position coordinates are transmitted through the remote communication unit 420. do.

Receiving the remote signal transmitted in this way from the remote management device to check the history, the EEPROM 440 is typically controlled by the EEPROM (Electrically Erasable Programmable Read Only Memory) according to the configuration of the control computer 410 and the peripheral device It is composed of a computer integrated into the computer 410 or a separate element, but if the management data has a large capacity and a large number of times of update, it uses a memory device in the form of a flash memory (RAM) or a RAM device made with a backup battery. .

The function of obtaining the dot / light-off time of the street lamp management method corresponds to the seventh process of the street lamp management method. As shown in FIG. 7A, the system driving program is operated, and the citizen's night vision time calculation program and the citizen's night vision time calculation variable are shown. A control computer 410 for driving a generation program, a GPS receiver 210 for receiving GPS information and providing visual and position information to the system, a remote communication unit 420 for communicating with an external remote management device, and a GPS receiver EEPROM (440) for storing the position information calculated from the 210, RTC (430) for driving the clock and operating the current time and date, input and output unit 450 and power supply unit 600 to display the operation state to the outside ) Are organically linked to each other.

The operation of the function for obtaining the point-off time is as shown in FIGS. 1 and 7B when power is supplied from the power supply unit 600 to the system, waiting for a signal from the GPS receiver 210 and counting a reception delay time. If the delay time exceeds the predetermined time, it is indicated as a GPS error.If the GPS signal is received within the predetermined time, the latitude information is extracted and repeated another latitude information is calculated to calculate the relative error. Analyze and determine the error by comparing the error and calculate the error of the latitude coordinates when it is not an error to take the information within the predetermined range to obtain the midpoint, save the new latitude in the EEPROM (440) and reset the location information error, the predetermined distance Information in which a larger error occurs is judged to be an error and a GPS error is displayed on the display unit.

Waiting for the external signal from the remote communication unit 420, receiving the local information code and updating and storing it in the EEPROM 440, while waiting for the GPS signal, counting the reception period, and comparing the time for which the reception period is delayed to determine the delay time. When the predetermined time is exceeded, it is indicated as a GPS error, and when a GPS signal is received within a predetermined time, the time information is extracted and repeated, another time information is extracted to calculate a relative error. Compensate for the delay time in the received time information when it is not an error by analyzing and determining, calculating the current time, correcting the RTC 430, resetting the time information error, and GPS signal for continuous correction of the RTC 430. Return to the waiting step.

Analyze the date fluctuations of the RTC 430 and determine whether there is a date fluctuation, calculates the morning and night citizens 'time and evening time and the citizens' evening time, and discards the latitude error information that causes an error and displays a GPS error on the display unit. The control computer 410 accesses the date of the day from the RTC 430, accesses the latitude coordinates from the EEPROM 440, and applies the variable to the CIT program to calculate the CIT.

The calculated civil fatality time is corrected by the local correction time of the EEPROM 440 to calculate the point and light off time of the day, and the streetlight driving unit 480 sends the streetlight operation signal by the RTC 470 to operate the streetlight 300. do.

The citizen's night time of the above operation is that the control computer 410 calculates the point-of-light management time of the street lamp by applying the position information and the time information received from the GPS receiver 210 as variables of the previously input citizen's night time time calculation program. Therefore, if the position of the system is P (lon, lat) and the date of the system is the date of the Sun's altitude and latitude coordinates. The variable is latitude = lat, date = date.

The above parameters are applied to a program that calculates the sun's altitude of -6 ° in the morning and evening standard hours, and the calculated time corresponds to the civil clearing time of one latitude point on the prime meridian with a 0 ° longitude. The time to operate the streetlight is calculated by compensating for the difference between twelve o'clock and the midpoint of the system's position P (the time the sun's center passes through the meridian) from the current time, or by taking into account the time taken into account in separate local conditions. . In the above, the 12 o'clock time from the current time of the system and the south center time and the time difference of the position P of the system are obtained by the 12: 00-m central time of the region of the position P of the system.

In addition, in some regions, the Sun-Nun time when the center of the sun passes through the meridian is equal to within the margin of error as long as the mid-distance time of the other region and the standard time on the same latitude. It is replaced by the longitude coordinates of the area so that the longitude coordinates of the streetlight installation area can be calculated without applying the longitude coordinates as a calculation variable of the citizens' time.

As such, replacing the longitude coordinate with the local standard time means that even if the latitude and longitude values are used as variables, the current time is used based on the standard time in the area, even if the local citizens' time is calculated. There is a time difference between 12 o'clock and standard time, and additional time is added and subtracted according to the topographical conditions, which leads to the inconvenience of managing one more unnecessary variable and the inconvenience of calculating the variable through a complicated process. Considered.

In addition, the remote management function corresponding to the thirteenth process of the street lamp management method includes a control computer 410 for driving a system, determining and processing a remote signal, and a remote communication unit for receiving a remote signal as shown in FIG. 8A. 420, a circuit current sensing unit 490 for detecting a conduction current of the streetlight driving circuit, an EEPROM 440 for storing received information, and a streetlight failure processing apparatus 500 for analyzing and processing a failure of the streetlight. And, the street light driver 480 for opening and closing the converter of the street light, and the power supply unit 600 for supplying the operating power to each of the system is configured to be organically connected to each other.

The operation of the remote management function is supplied to the system from the power supply unit 600, as shown in Figure 8b attached to the control computer 410 drives the streetlight operation program through the streetlight driver 480 streetlight 300 Operate and monitor and handle the failure of the street lamp through the streetlight failure handling apparatus 500, and update and store the failure handling result in the EEPROM 440 with the date and time of the system. The failure processing result is transmitted through the remote communication unit 420.

The transmitted failure processing information is received and confirmed by the remote device, and when the power is supplied and the street lamp 300 is operated, it waits for receiving the data code from the remote communication unit 420. It is determined whether the data request code is received, and if the data request code is transmitted, the date and time of the system, the position coordinates, the operation state, the fault handling record and the historical data of the EEPROM 440 are transmitted to the outside through the remote communication unit 420.

The transmitted information is received and confirmed by the remote device, and if it is not a data request code, it is determined whether it is history data, and if it is history data, the history data is added by adding a date and time to the EEPROM 440. It is determined whether it is history data or operational data, and if it is an operational data code, the new data is stored in the EEPROM 440. Otherwise, the received data is discarded.

The remote communication unit 420 is a mobile communication means for supporting long distance data communication and wireless data communication means using a radio wave and a communication speed is fast and data communication characteristics in order to communicate with the central remote management server 100 at a long distance according to the communication conditions Selective configuration consisting of wireless Internet communication means, etc., and wireless infrared communication for adjacent short-range communication that can be applied when mainly using a remote management means in the form of a portable manager configured separately for maintenance work and status check Means) and radio communication means using radio waves, and communicate with the communication conditions of the central management means by selecting or combining a long range and short range communication means such as the portable remote management apparatus 110. Can be.

The function of managing the street lamp by using the daylight signal corresponds to the 14th process of the streetlight management method. As shown in FIG. 9A, a control computer for processing the daylight signal and the satellite signal, and the satellite signal 410 are received. GPS receiver 210, EEPROM 440 for storing data, daylight sensor 460 for detecting external brightness, RTC 470 for driving the current time of the system, and street light 300 The streetlight driver 480 for opening and closing the converter and the power supply unit 600 for supplying power to each unit are configured to be organically operated.

The function of managing the street lamp using the daylight signal is shown in FIGS. 1 and 9A when the power is supplied from the power supply unit 600 to the system, the control computer 410 drives the system, and the control computer 410. Receives the satellite signal from the GPS receiver 210, extracts the location information, corrects the error, obtains new coordinates, and stores the coordinate values in the EEPROM 440. The satellite signal is received to correct the RTC 470.

Using the date of the RTC 470 and the location information of the EEPROM 440 as variables, the point-off time according to the sunrise / mole period is calculated every day. The RTC 470 determines the error, and if it is an error, adjusts the sampling time and the number of times of the signal received from the daylight sensor 460 to safely operate the street light from sudden changes and temporary interference of the daylight signal.

If the error is not corrected, the elapsed time after the RTC 470 correction is counted. If the RTC 470 is not corrected for a predetermined time, the street lamp is operated according to the main light signal. On the other hand, if the RTC 470 is corrected within a predetermined time, the predetermined time band is calculated to apply the daylight signal before and after the point and turn off time of the citizen's clear time period, and the RTC 470 is designated before and after the lighting and turning off time. It is determined whether the predetermined time band is applied, and if the predetermined time band, the street lamp is operated according to the main light signal. When the RTC 470 is not in the predetermined time band, the RTC 470 returns to perform the initial process.

The safety termination function of the street lamp management method corresponds to the fifteenth process of the street lamp management method, as shown in FIG. 10A, a control computer 410 and a central remote management server that operate a system driving program and monitor power. The remote communication unit 420 communicating with 100, the preliminary power supply unit 610 capable of charging and discharging, and the power supply unit 600 for receiving an external power supply and supplying operating power to each system are organically connected.

Operation of the safety shutdown function configured as described above is when the commercial power is supplied to the system from the power supply unit 600, as shown in Figure 1 and 10b of the accompanying drawings, the system starts to drive and charge the preliminary power supply unit 610 and Monitor the supply of commercial power. When the commercial power is cut off, the reserve power is continuously supplied so that the power supply of the system is not cut off, and the operation of the system is operated for a predetermined time while the power supply is cut off.

If the power outage of the commercial power supply continues for more than a predetermined time by determining the power failure time, the processing of the system is completed with the reserve power, the electrostatic lock is stored and sent out remotely, and the system is safely shut down when the processing of the system is completed.

When the power failure is restored within a predetermined time and commercial power supply is resumed, the system operates normally with the commercial power of the power supply unit 600, returns to charge the reserve power, and continues monitoring the commercial power.

The present invention configured and operated as described above can prevent power waste by monitoring the operating state of the street lamp and taking safe operation such as power saving in case of failure.

In addition, according to the weather compensation management method of the present invention, because it detects daylight and compensates for the ambient brightness due to weather changes, there is an effect of improving the function to operate the street lamp in all weather.

In addition, according to the method for displaying the operating state of the system of the present invention, it is possible to immediately determine the management state of the street light at a short distance by means of displaying the fault and the management state to the outside through the input and output unit without operating a separate device or through remote communication. It has a convenient effect that makes it possible.

In addition, according to the method of recognizing the position of the street light by the GPS information of the present invention, since the error is applied to the normal data only by verifying the error of the code to reduce the malfunction of the system and improve the accuracy of the GPS information by improving the conditions of using the GPS information It has the effect of working smoothly.

In addition, according to the method of correcting and recognizing the position information with the GPS information of the present invention, by verifying the error and error of the code, by correcting the error to reduce the position error and increase the accuracy, it is possible to recognize the exact position and adjacent street light Make it clearly visible.

In addition, according to the system of the present invention, the system is installed in the field together with the street lamp without artificially setting the system, and when the power is supplied, the GPS receiver automatically recognizes the use position and the correct current time, so that the street lamp can be detected at the correct time without error. It turns on and off to facilitate installation and maintenance.

In addition, it is possible to remotely manage a plurality of street lights through the communication system of the present invention can achieve a convenient and quick management, and by selectively configuring a two-way remote communication unit for the purpose of short-range and long-distance use remote management device and portable It has the effect of smoothly communicating with the central management means composed of the management device and purpose.

In addition, according to the method of the system of the present invention to handle the failure, by detecting the operation of the street lamp, calculates the failure information, such as malfunction or flicker occurs, and cut off the power supply to the street lamp to prevent waste of power and secure the street lamp It is effective to process.

In addition, according to the method for managing fault information of the present invention, when two or more street lamps are configured through a single or branched circuit, the detected current and the current of the circuit are detected and compared with each other based on the information received from the street lamp fault handling apparatus. It is possible to compare the operation status of the circuit and the fault analyzer by the fault analysis that judges the abnormality.

In addition, according to the method for managing the fault information of the present invention, the fault information is calculated from the signal of the state monitor and stored in the memory means for each date of the system clock operated by the control computer. To be.

In addition, according to the method for remotely monitoring the fault information of the present invention, when the fault is calculated by analyzing the signal of the street lamp state monitoring unit, the fault information is stored in the memory means for each date of the system, and transmitted through the bidirectional remote communication unit, When a request is made from the communication unit, the fault information stored in the memory means by date is transmitted to the bidirectional remote communication unit so that the fault information can be checked remotely.

In addition, according to the method for managing the history information of the present invention, the street lamp by receiving the installation information, the parts replacement information and the troubleshooting information of the street lamp from the bidirectional remote communication unit, and stores in the memory means for each date of the system clock operated by the control computer The history of the system can be entered into the system so that the system can check the history if necessary.

In addition, according to the method for calculating the street light point / light off time of the present invention, the management area of the street light is found by the latitude information received from the GPS receiver as a parameter of the program for calculating the citizens' fat time, and according to the current time analyzed from the GPS information itself. It is easy to control the lighting of the street lamp by calculating the lighting time.

It is possible to combine the above-mentioned configuration and action or to operate variously for various purposes with various settings, to actively handle failure analysis and management, and to provide the administrator with the management of location information and history information necessary for maintenance. It has an effect.

1 is a block diagram showing the configuration of the present invention street light management device.

Figure 2a is a block diagram showing the configuration of the visual correction function of the present invention, Figure 2b is a flow chart showing the operation of the visual correction function.

FIG. 3A is a block diagram illustrating the location information calculation function of the present invention, and FIG. 3B is a flowchart showing the operation of the location information calculation function.

Figure 4a is a block diagram showing the configuration of the fault handling function of the present invention street lamp, Figure 4b is a flow chart showing the operation of the fault handling function of the street light.

5A is a block diagram showing the configuration of a failure management function such as the present inventors security, and FIG. 5B is a flowchart showing the operation of the failure management function such as security.

Figure 6a is a block diagram showing the configuration of the history management function of the present invention, Figure 6b is a flow chart showing the operation of the history management function.

Figure 7a is a block diagram showing the configuration of the light-on-time calculating function of the present invention, Figure 7b is a flow chart showing the operation of the light-on-time calculating function.

Figure 8a is a block diagram showing the configuration of the present inventors remote management function, Figure 8b is a flow chart showing the operation of the remote management function.

Figure 9a is a block diagram showing the configuration of the daylight compensation function of the present invention, Figure 9b is a flow chart showing the operation of the daylight compensation function.

Figure 10a is a block diagram showing the configuration of the present invention safety shutdown function, Figure 10b is a flow chart showing the operation of the safety shutdown function.

Figure 11 is a flow chart showing the operation of the inventor street light management device.

* Description of the symbols for the main parts of the drawings *

100: central remote management server 110: portable remote management device

200: GPS signal transmitter 210: GPS receiver

300: street light 410: control computer

420: remote communication unit 430: ID unit

440: EEPROM 450: input / output unit

460: daylight detection unit 470: RTC

471: rechargeable battery 480: street light driving unit

490: circuit current detection unit 500: fault handling device

510: microcomputer 520: state detection unit

530: fault handling unit 540: PLC communication unit

550: power supply unit 560: ID unit

570: setting unit 580: display unit

Claims (19)

A control computer for embedding and operating an operating program of the system; A GPS receiver for providing location information and visual information to a control computer; An RCT that drives the clock and operates the current time and date; An input / output unit connected to a control computer to input a signal and display operation information; A streetlight driver for controlling power supplied to the streetlight by a signal of a control computer; A daylight detecting unit connected to the control computer for detecting an external brightness signal and converting the brightness signal into a digital signal and providing the same to the control computer; A circuit current sensing unit for sensing an energizing current of the street light power circuit and providing the control computer to the control computer; A power supply unit supplying an operating power required for each system unit; In the streetlight management device using a telecommunication and GPS receiving streetlight management device consisting of, Memory means for storing and managing operating conditions, fault information, and history information of the street light; An ID unit connected to the control computer to give an individual identification number; A remote communication unit configured to be connected with the control computer to bi-directionally communicate information through wireless communication; Microcomputer that operates the trouble-shooting program, a status detector that detects the operation status of the streetlight and converts it into an input signal of the microcomputer, a fault-handling unit that opens and closes the streetlight path according to the microcomputer's signal, and troubleshoots the streetlight path. PLC communication unit for transmitting signals, power unit for supplying power to the system by the power supplied to the street lamp, ID unit for individual classification recognition, setting unit for setting the fault analysis and processing standards, and display unit for displaying the status of fault processing A fault handling apparatus for detecting an operation state of a street light, analyzing a failure by itself, displaying a processing state, and transmitting the processing state to the outside through a PLC communication unit; A PLC communication unit connected to the control computer and communicating with a signal transmitted from the failure processing apparatus; Street light management device, characterized in that for managing the operation status and fault handling status of the street light. delete delete delete delete delete delete Means for calibrating the RTC with the time information received from the GPS receiver, means for calculating the position of the street light from the position information received from the GPS receiver, and calculating the citizen's fat time using the GPS receiver latitude information and date variables as parameters In the street lamp management method for managing the street lamp by means of obtaining the time, the fault handling means for analyzing and processing the failure of the street lamp, the means for managing the failure based on the current of the street lamp circuit and the fault handling information, History management means to check the history information if necessary by storing the installation information, replacement parts of the street light inputted from the outside, and troubleshooting information and failure information calculated by itself in the memory means for each system clock date operated by the control computer. and; Receive a declaration code, an information code, and a checksum code classified by the nature of the information through a telecommunication device, analyze the information to update the items of the memory means, and the control computer updates the updated data. Therefore, the first operation of remotely managing the system by an external signal while operating the system, and when the system operated as described above fails or handles the failure of the street light or the operation state of the street light changes, A second action for transmitting the fault content or operation state including the date and time, ID, and location information to the outside, and a request for the information from the remote communication means to access the system and the fault content of the second action and the memory means By sending the processing record and the history information to the outside, the external remote management means sends the operation status and the history information together with the location information of the street lamp. Street management method characterized in that it further comprises a means for remote management according to the third action to confirm. delete delete delete delete delete delete delete delete delete delete delete