KR101583255B1 - Apparatus for signal information analysis of railroad crossing - Google Patents

Abstract

A signal analyzer for railroad crossing that stores and analyzes the operation status of the crossing control device, alarm, breaker, and other devices, and provides power to the power supply by redundant power supply and protects the device from lightning A power supply device for supplying stable power so that the information analysis apparatus can operate normally; First and second lightning protection units for protecting the information analysis apparatus from lightning strikes from the input / output or input port of the power source or the communication line; An input device for collecting equipment operation information and fault information through a control unit for controlling a breaker / alarm / safety equipment installed in a railroad crossing; A main processor unit for storing the collected device operation information and the failure information in real time, determining whether there is an abnormality in the crossing equipment based on the equipment operation information and the failure information, and providing information on the determined abnormality; An output device for transmitting a failure of the information analyzing device to the control unit and transmitting a driving signal to the ventilation fan; An interface card for transmitting operation and failure information of the crossing equipment to the remote station operating system; And a display device for visually displaying operation and failure information of the crossing equipment.

Description

Technical Field [0001] The present invention relates to a railway cross-

The present invention relates to an information analyzing apparatus for a railway crossing, and more particularly, to an information analyzing apparatus for a railway crossing, which stores and analyzes operation states of an alarm, a breaker, and other devices, The present invention relates to a railway crossing signal information analyzing apparatus capable of protecting a device from a lightning stroke.

Generally, railroad crossings are equipped with alarm devices, which are alarm devices, breaker devices, crossing barrier devices, signal information analyzing devices for analyzing and monitoring faults of alarm devices and breakers for traffic safety.

Here, the alarm is a device that blocks the crossing in advance to avoid trouble on the train when entering the train in the crossing, and prevents the accidents such as pedestrian crossing or vehicle collision by generating an alarm to secure the course of the train safely it means.

Since such an alarm is composed of various electric circuits, it is necessary to quickly detect a fault and remove the fault, since a fault such as disconnection of a wire or connection failure occurs. At this time, the operation state information of the alarm is acquired, It is the signal information analyzing device that plays a role in finding the fault site through analysis.

A conventional signal information analyzing apparatus for a railroad crossing is disclosed in the following Patent Document 1: Korean Patent Laid-Open Publication No. 2002-0019162 (published on Mar. 12, 2002).

The prior art disclosed in Patent Document 1 includes a crossing signal information analyzing unit, a multiplexing unit, a main part, and a branching unit. It can instantly display the field information of the crossing in the main apparatus and the branching apparatus, Provides a railroad crossing remote monitoring system and its information management method that can simultaneously construct a database without interruption.

Korean Unexamined Patent Publication No. 2002-0019162 (published on March 12, 2002)

However, since the conventional technique uses a single power source (main power source), there is a disadvantage that the operation of the device is stopped when the main power source is out of order and the stability is poor, and the device can not be protected from lightning.

It is an object of the present invention to provide a crossing control device which stores and analyzes operation states of an alarm, a circuit breaker and other devices, And to provide a railway crossing signal information analyzing apparatus which is designed to ensure safety in a railroad crossing.

It is another object of the present invention to provide a railroad crossing signal information analyzing apparatus capable of protecting a device from a lightning strike through a lightning protection apparatus.

It is still another object of the present invention to provide a railway crossing signal information analyzing apparatus which enables an administrator to easily confirm whether or not an input voltage abnormality or an output voltage abnormality exists.

In order to accomplish the above object, a railway crossing signal information analyzing apparatus according to the present invention comprises: a power source device for supplying stable power so that the information analyzing device can operate normally; First and second lightning protection units for protecting the information analysis apparatus from lightning strikes from the input / output or input port of the power source or the communication line; An input device for collecting equipment operation information and fault information through a control unit for controlling a breaker / alarm / safety equipment installed in a railroad crossing; A main processor unit for storing equipment operation information and failure information collected through the input device in real time, determining whether there is an abnormality in the crossing equipment based on the equipment operation information and the failure information, ; An output device that transmits a failure of the information analyzing device to the control unit under the control of the main processor unit and transmits a driving signal to the ventilation fan; An interface card for transmitting operation and failure information of the crossing equipment to a remote station operating system under control of the main processor unit; And a display device for visually displaying operation and failure information of the crossing equipment under the control of the main processor unit.

In addition, the railway crossing signal information analyzing apparatus according to the present invention further includes an automatic time correction device for receiving the standard time from the satellite and correcting the time in real time.

The first lightning protection unit protects the information analyzing apparatus from lightning strikes from the power source and the input / output of the communication line, and the second lightening protection unit protects the information analyzing apparatus from the lightning stroke that flows into the input port .

The first lightning protection unit includes a surge protector for removing an overvoltage input to the input power source and passing a primary surge; A first fuse that is automatically shut off to protect the device from surges when the current output from the surge protector is an overcurrent; A master power supply relay controller for outputting power supplied through the first fuse to the master power supply or for interrupting the master power supply when the first surge voltage is supplied from the surge protector; A master power LED indicator for indicating a master power supply state under the control of the master power relay controller; A power supply output unit for outputting power from the master power relay control unit; A third fuse for shutting off power when an overcurrent flows through the power supply output from the power output unit; And a power measuring unit for measuring a voltage level of a power source output through the third fuse.

The first lightning stroke circuit unit includes a second fuse for shutting off or supplying a power source including a surge output from the master power relay control unit. A slave power supply delay control unit for delaying a power supply time through the second fuse; A slave power supply relay controller for supplying power through the second fuse to the power output unit as a slave power supply under the control of the slave power supply delay control unit; And a slave power LED indicator for indicating a slave power supply status under the control of the slave power supply relay control unit.

The power supply unit may include a first fuse for blocking an overcurrent flowing into an input power source; A master DC / DC converter for converting the master power through the first fuse to a DC power of a predetermined level; An automatic switching unit for controlling the output of the power source and the power outputted from the master DC / DC converter or controlling the output of the slave power source; A second fuse for blocking when an overcurrent is included in the power supplied through the automatic transfer unit; A slave DC / DC converter for converting power from the second fuse to a predetermined DC power and supplying the power to the automatic switching unit via a slave power supply; A third fuse for shutting off power when an overcurrent is included in the power output from the automatic switching unit; A power measuring unit for measuring a level of power outputted through the third fuse; And a reset switch for resetting the automatic transfer unit.

The automatic switching unit may include a relay control unit for supplying the input power to the slave power supply; A power controller for selecting and supplying a master power or a slave power; A power LED display unit for indicating whether the power supplied according to the control of the power control unit is a master power or a slave power; A power error detection unit for detecting an error of the master power supply or the slave power supply; A voltage detector for detecting a voltage level of the master power supply or the slave power supply; An output power delay control unit for delaying the output power by a predetermined time; And a power output unit for outputting either the master power or the slave power to the power source under the control of the power control unit.

The main processor unit may include a power supply unit for supplying driving power; A buffer for buffering equipment operation information and failure information collected through a bus; A central processing unit that stores collected information received through the buffer in a storage unit in real time and controls display and transmission of equipment operation status or failure information; A temperature sensor for detecting the temperature of the information analyzing apparatus and transmitting the detected temperature to the central processing unit; And a communication and information display interface device connected to the central processing unit for transmitting output information or displaying status information.

According to the present invention, it is possible to store and analyze operation states of an alarm, a circuit breaker, and other devices, which are crossing control devices, in real time, and to provide power supply safety by redundant power supply devices.

In addition, according to the present invention, there is an advantage that a device can be protected from a lightning strike through a lightning protection device.

In addition, according to the present invention, there is an advantage that the manager can easily check whether the input voltage is abnormal or the output voltage is abnormal.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a railway crossing signal information analyzing apparatus according to a preferred embodiment of the present invention;
FIG. 2 is a front view of a railway crossing signal information analyzing apparatus according to the present invention,
FIG. 3 is a configuration diagram of an embodiment of the power supply device of FIG. 1,
Fig. 4 is an external view of the power supply device of Fig. 3,
Fig. 5 is a configuration diagram of an embodiment of the first lightning stroke circuit portion of Fig. 1,
Fig. 6 is an external view of the first lightning stroke circuit portion of Fig. 5,
FIG. 7 is a block diagram of an embodiment of the main processor unit of FIG. 1;
8 is an external view of the main processor unit of Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a railway crossing signal information analyzing apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an overall configuration diagram of a railway crossing signal information analyzing apparatus according to a preferred embodiment of the present invention, and FIG. 2 is a front view of an information analyzing apparatus of a railway crossing.

The apparatus for analyzing signaling information of a railway crossing signal according to the preferred embodiment of the present invention includes first and second lightning stroke circuit units (SPUs) 110 and 120, a bus 101, a main processor unit (MPU) 130, an interface card IFC 140, an input device DIU 150, an output device DOU 160, an automatic time correction device (GPS) 170, a power supply unit (PSU) 180, And a display device (LCD) 190.

1, reference numeral 10 denotes a control unit. These control units are installed in railway crossings to monitor and control alarms, breakers and other safety equipment.

The power supply 180 serves to supply stable power so that the information analysis apparatus can operate normally. Here, the power supply 180 is redundantly used as a power master and a slave for stable power supply.

As shown in FIG. 3, the power supply unit 180 includes a first fuse 201 that cuts off when an overcurrent flows into an input power source (DC 24V OUT); A master DC / DC converter 202 for converting a master power through the first fuse 201 into a DC power of a predetermined level; An automatic switching unit 210 for controlling the output of the power source and the power outputted from the master DC / DC converter 202 or controlling the output of the slave power source; A second fuse 204 for shutting off when an overcurrent is included in the power supplied through the automatic switching unit 210; A slave DC / DC converter 205 for converting power from the second fuse 204 to a predetermined DC power and supplying the power to the automatic switching unit 210 as a slave power source; A third fuse 206 for shutting off power when an overcurrent is included in the power output from the automatic switching unit 210; A power measuring unit 207 for measuring a level of the power outputted through the third fuse 206; And a reset switch (203) for resetting the automatic switching unit (210).

The power supply control unit 211 controls the automatic switching unit 210 to turn on / off the output voltage by detecting the presence or absence of an output voltage of the master DC / DC converter 202 and to switch the slave power supply when the master power supply is abnormal. A relay control unit (212) for switching the power inputted according to the control of the power control unit (211) to a slave power supply; A power LED display unit 213 for indicating whether the power supplied by the power control unit 211 is a master power or a slave power; A power error detecting unit 214 for detecting an abnormal state and a use state of the master DC / DC converter 202 and the slave DC / DC converter 205; A voltage detecting unit 215 detecting the output voltages of the master DC / DC converter 202 and the slave DC / DC converter 205 in real time and monitoring the power supplied to each board; An output power delay controller 216 for delaying the output power by a predetermined time to minimize a peak voltage according to a voltage output; And a power output unit 217 for outputting either the master power or the slave power to the power source under the control of the power control unit 211.

The first lightning strike protection unit 110 protects the information analysis apparatus from lightning strikes from the power source or the input / output of the communication line.

As shown in FIG. 5, the first lightning strike protection unit 110 includes a surge protector 301 for removing an overvoltage input to an input power source (DC 24V MAIN) and passing a primary surge; A first fuse 302 that is automatically shut off when the current output from the surge protector 301 is an overcurrent to protect the device from a surge; A master power relay control unit 303 for outputting the power supplied through the first fuse 302 to the master power supply or for interrupting the master power supply when the first surge voltage is supplied from the surge protector 301; A master power LED indicator 304 for displaying a master power supply status under the control of the master power relay controller 303; A power supply output unit 309 for outputting power from the master power relay control unit 303; A third fuse 310 for shutting off the power when an overcurrent flows in the power supply output from the power output unit 309; A power measuring unit 311 for measuring a voltage level of a power source output through the third fuse 310; A second fuse 305 for shutting off or supplying a power source including a surge output from the master power relay control unit 303; A slave power supply delay control unit (306) for delaying a power supply time through the second fuse (305); A slave power supply relay control unit 307 for supplying power through the second fuse 305 to the power output unit 309 as a slave power supply under the control of the slave power supply delay control unit 306; And a slave power LED indicator 308 for indicating a slave power supply state under the control of the slave power relay controller 307. [

The second lightning strike protection unit 120 protects the information analysis apparatus from lightning strikes from the input port. It is preferable that the second lightning strike protection unit 120 has the same structure as that of the first lightning stroke protection unit 110 shown in FIG.

The input device 150 collects equipment operation information and failure information through a control unit that controls a breaker / alarm / safety equipment installed in a railway crossing, and transmits the collected equipment operation information and failure information to the main processor unit 130.

The main processor unit 130 stores device operation information and failure information collected through the input device 150 in real time, determines whether or not the crossing equipment is abnormal based on the equipment operation information and the failure information, And provides information on the abnormality.

As shown in FIG. 7, the main processor unit 130 includes a power supply unit 401 for supplying driving power; A buffer 402 for buffering equipment operation information and failure information collected via a bus (BUS); A central processing unit (403) for storing the collected information received through the buffer (402) in the storage unit (404) in real time, and controlling display and transmission of equipment operation status or failure information; A temperature sensor 407 for detecting the temperature of the information analyzing apparatus and transmitting the detected temperature to the central processing unit 403; A communication and information display interface device 408 connected to the central processing unit 403 for transmitting output information or displaying status information; A real time clock generator 405 for generating a real time clock for data storage time synchronization; And a CPLD 406 for duplication of the central processing unit 403.

The storage unit 404 includes a flash memory, a system memory (SDRAM), and a storage board for storing data.

The communication and information display interface device 408 includes RS-232C for setting debugging and cross-over information of the main process unit 130, system re-driving by manual switching of the main processor unit 130, WATCH-DOG RESET for system initialization and restart by automatic operation of processing unit, LED DISPLAY for displaying current operation status, USB HOST for data backup by USB memory stick, USB DEVICE for updating drive program, data setting And USB for program debugging, and IFC INTERFACE for communicating with the interface card board via the backplane.

The output device 160 transmits a failure of the information analyzing device to the control unit 10 under the control of the main processor unit 130 and transmits a driving signal to the ventilation fan.

The interface card 140 transmits the operation and failure information of the crossing equipment to the remote station operating system under the control of the main processor unit 130. This interface card 140 enables remote diagnosis.

The display unit 190 visually displays operation and failure information of the crossing equipment under the control of the main processor unit 130.

The automatic time correction device 170 receives the standard time from the satellite and corrects the time in real time.

The operation of the railway crossing signal information analyzing apparatus according to the preferred embodiment of the present invention will now be described in detail.

2 is connected to the control unit 10 of the railroad crossing, and when the power is supplied, the electromagnetic wave is removed from the power supply unit 180 and the power supply is appropriately controlled, .

That is, as shown in FIG. 3, the power source device 180 receives the input power source (DC24V OUT) into the automatic switching unit 210 and simultaneously inputs the power source DC24V OUT to the first fuse 201. The first fuse 201 cuts off the power when the overcurrent flows into the input power source, and supplies the input power to the master DC / DC converter 202 when the overcurrent does not flow.

The master DC / DC converter 202 converts an input power source (DC 24V) to a predetermined DC voltage (DC 12V) and supplies the DC voltage to the automatic switching unit 210. The power control unit 211 of the automatic switching unit 210 detects an abnormality of the voltage output from the master DC / DC converter 202 and turns on / off the output voltage of the power output unit 217. For example, when there is an abnormality in the voltage output from the master DC / DC converter 202, that is, when a predetermined DC voltage is not generated from the master DC / DC converter 202, 2187, and generates a relay control signal to switch the relay control unit 212 to the slave power supply. Otherwise, when the master power is normal, the power output of the power output unit 217 is turned on, and the relay control unit 212 controls the relay so that power is not supplied to the slave side.

If the power supplied from the relay control unit 212 is switched to the slave power supply by the master power supply or more, the second fuse 204 senses whether the overcurrent is included in the supplied power supply. If the overcurrent is included, do. Otherwise, if the overcurrent is not included and the normal voltage state is present, the input power is output to the slave DC / DC converter 205. [ The slave DC / DC converter 205 converts power from the second fuse 204 to a DC power source (DC 12V) and supplies the power to the automatic switching unit 210 as a slave power source. Then, the power output unit 217 outputs the slave power output from the slave DC / DC converter 205 to the power source under the control of the power control unit 211.

When the power is output from the power output unit 217 of the automatic switching unit 210, the third fuse 206 cuts off the power when the output power source includes the overcurrent, and when the output power is normal, And transmits the power to the power measuring unit 207. The power measuring unit 207 measures the level of power output through the third fuse 206. The power measurement value thus measured is transmitted to the main processor unit 130.

In addition, the power LED display unit 213 of the automatic switching unit 210 indicates whether the power supplied by the power control unit 211 is a master power or a slave power. 4, the main power LED 181 for displaying the main power supply state, the auxiliary power LED 182 for displaying the auxiliary power (slave power) supply state, the power supply for operating the power supply on or off A switch 183, and a voltage status display LED 184 (185) for indicating whether the measured power source is in a high voltage state or a low voltage state.

The power supply error detection unit 214 of the automatic switching unit 210 detects an abnormality and a use state of the master DC / DC converter 202 and the slave DC / DC converter 205, . The voltage detection unit 215 detects the output voltages of the master DC / DC converter 202 and the slave DC / DC converter 205 in real time and transmits the detected voltages to the power control unit 211, To be monitored. In addition, the output power delay control unit 216 delays the output power from the power output unit 217 by a predetermined time to minimize the peak voltage according to the voltage output.

When the power source 180 supplies driving power to the information analysis apparatus 100, the information analysis apparatus 100 starts operation and receives the operation state collected from the control unit 10 via the input apparatus 150 Information and failure information are collected and transferred to the main processor unit 130 via the bus 101 in the form of data that can be recognized by the main processor unit 130. [

Here, when data and power are input / output from the input port, the power port, and the communication port, a lightning stroke generated through the input / output port or the like may flow into the information analyzing apparatus.

Accordingly, in the present invention, the lightning striking through the power source, the communication port, the input port, and the like is removed through the first lightning strike protection unit 110 and the second lightning strike protection unit 120, do.

For example, as shown in FIG. 5, the first lightning strike protection unit 110 uses a surge protector 301 to apply an overvoltage to the input power source (DC24V MAIN) using a GDT, a varistor, a TVS diode, Remove, and let the primary surge pass. When the current outputted from the surge protector 301 is normal, the first fuse 302 passes the input power as it is and supplies it to the master power relay controller 303. At this time, when an overcurrent is included in the input power source, the input power is interrupted due to the temperature due to the overcurrent, thereby preventing the input power including the overcurrent from being supplied to the master power relay control unit 303. This protects the device primarily from the surge.

The master power supply relay controller 303 transmits the power supplied through the first fuse 302 to the power output unit 309 through the master power supply and outputs the master power through the master power LED indicator 304 to the outside .

If the primary surge voltage bypassed from the surge protector 301 is not supplied through the first fuse 303 and the primary surge voltage is supplied from the surge protector 301, the master power supply relay controller 303 interrupts the master power supply, And transmits the surge voltage to the second fuse 305. The second fuse 305 blocks the overcurrent of the power source including the surge output from the master power relay control unit 303 when the overcurrent is included. If the overcurrent is below the predetermined level, the second fuse 305 disconnects the overcurrent from the slave power delay control unit 306 and the slave power relay control unit 307, respectively.

The slave power supply delay control unit 306 delays the power supply time of the slave power supply relay control unit 307 by a predetermined time (about 1 to 3 seconds) when the power is supplied through the second fuse 305. The delay of the power supply time minimizes the loss due to the secondary surge.

The slave power supply relay control unit 307 delays the power supply through the second fuse 305 for a predetermined time according to the control of the slave power supply delay control unit 306 and supplies the slave power supply unit 309 with the slave power supply do. At this time, the slave power LED indicator 308 indicates the slave power supply (auxiliary power) supply status. In addition, the power output unit 309 outputs the main power transmitted from the master power relay controller 303 or the auxiliary power supplied through the slave power relay controller 307 to the power supply.

When the power is outputted from the power output unit 309, the third fuse 310 blocks the output power when the overcurrent flows to the output power source, thereby preventing the overcurrent from being supplied to the rear end and damaging the device. If there is no overcurrent in the output power source, the power measuring unit 311 measures the voltage level of the output power and transmits the measured voltage to the main processor unit 130.

6 is a diagram illustrating a state of a power supply state and a measured voltage state in the first lightning strike protection unit 110. The main power supply state display LED 111 and the auxiliary power supply state display LED 112 are used to display current This allows the outside to know whether the power supply is main power or auxiliary power. In addition, the status of the supply voltage is displayed through the measurement power indicator LEDs 113 and 114.

The first lightning strike protection unit 120 has the same structure as the first lightning strike protection unit 110 and protects the equipment of the information analysis apparatus from the lightning strike through the input port.

Next, the main processor unit 130 stores operation information and failure information of the crossing control devices input through the input device 150 in real time, determines whether or not the crossing control devices are abnormal, and transmits the information to the administrator .

For example, as shown in FIG. 7, the main processor unit 130 supplies power for driving in accordance with a power source input from the power source unit 401 to a portion of the main processor unit 130 that requires power.

When power is supplied, the central processing unit 403 is activated, and the buffer 402 buffers the equipment operation information and the failure information collected through the bus (BUS) and transfers the information to the central processing unit 403.

The central processing unit 403 stores the collected information received through the buffer 402 in a storage board of the storage unit 404 in real time. And analyzes the received collected information to control the display and transmission of the equipment operation status or failure information. Here, the display of the equipment operation status or the failure information is performed through the LED display of the communication and information display interface device 408. [

FIG. 8 shows an example of the LED display. The LED display includes a power lamp 131 for displaying a power state. When power is supplied, the LED lamp is continuously lit (preferably, a green lamp is lit). And displays the operation status of the device through the operation lamp 132. In other words, the operation lamp 132 is flickered in the main operation, and turned on in the standby state. In addition, a backup lamp 133 indicates a data backup state. For example, during the data backup, the backup lamp 133 flashes for one second. When the data backup is completed, the backup lamp 133 flashes for three seconds. When a data backup error occurs, the backup lamp 133 lights up. The backup lamp 133 is turned off. The fault lamp 134 also indicates the factory or steady state of the device. For example, when a failure occurs in the apparatus, the failure lamp 134 is turned on and the failure lamp 134 is turned off in normal operation. The status of the main processor unit 130 is displayed through the reset switch 135. For example, when the main processor unit 130 is operating abnormally or when the main processor unit 130 is switched, the reset switch 135 is operated to reset the device. In addition, the backup switch 136 is used to start the backup while the USB memory stick is plugged in. When the data stored in the main processor unit 130 is backed up to the memory stick via the USB host 137, it is used together with the backup switch. Finally, the URP 138 is used to establish connection to the personal computer (PC) to set the crossing information, and debug the main processor unit board through the personal computer. In addition, the transmission state and the reception state of the data are displayed by using the transmission lamp 139a and the reception lamp 139b.

The temperature sensor 407 measures the internal temperature of the information analyzer in real time and transmits the measured temperature to the central processing unit 403. The central processing unit 403 retrieves the sensed temperature, 40 ° C), the ventilation fan control signal is generated through the output device 160. The ventilation fan operates according to the ventilation fan control signal to lower the internal temperature of the information analysis apparatus.

In the meantime, the main processor unit 130 is implemented in a redundant manner in order to achieve stability. For this, a CPLD 406 is provided, and the duplication of the central processing unit 403 is realized.

The communication and information display interface device 408 includes RS-232C for setting debugging and cross-over information of the main process unit 130, system re-driving by manual switching of the main processor unit 130, WATCH-DOG RESET for system initialization and restart by automatic operation of processing unit, LED DISPLAY for displaying current operation status, USB HOST for data backup by USB memory stick, USB DEVICE for updating drive program, data setting And USB for program debugging, and IFC INTERFACE for communicating with the interface card board via the backplane.

As is well known, the main processor unit 130 analyzes the information collected from the crossing apparatus and transmits analysis information to the interface card 140 when it is analyzed as an operation abnormality or a device abnormality. The interface card 140 transmits operation and failure information of the crossing equipment to the remote station operating system under the control of the main processor unit 130. A remote station operating system via the interface card 140 enables the remote diagnosis of the crossing equipment, and the administrator can remotely and conveniently check the status of the crossing equipment without having to stay in the crossing at all times.

In addition, the signal information analyzing apparatus of the present invention automatically corrects the time information through the automatic time compensating apparatus 170. For example, the automatic time correction device 170 receives the standard time from the GPS satellite and corrects the time in real time. To do this, it receives and amplifies the GPS satellite signal through the antenna, and processes the standard time received through the antenna through the GPS module. And transmits the standard time to the main processor unit 130 through the decoder. The main processor unit 130 determines that the GPS device is out of order if the internal communication with the automatic time correction device 170, which is a GPS device, is not performed for a predetermined time, and displays it on the display device 190.

The display device 190 displays the operation status and failure information of the crossing devices on the screen under the control of the main processor unit 130. For example, it is possible to display the current time, the relay status, the failure information, the system internal status, and the GPS channel display.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

The present invention is effectively applied to a technique for collecting and analyzing information of various equipment installed at a crossing, storing and analyzing in real time, and transmitting abnormal condition information to a remote station operating system.

100: Railway crossing signal information analyzer
110, 120: first and second lightning protection units
130: main processor unit (MPU)
140: Interface card
150: input device
160: Output device
170: Automatic time correction device
180: Power supply
190: Display device

Claims (8)

A power supply device for supplying stable power so that the signal information analyzing device can operate normally;
First and second lightning protection units for protecting the information analysis apparatus from lightning strikes from the input / output or input port of the power source or the communication line;
An input device for collecting equipment operation information and fault information through a control unit for controlling a breaker / alarm / safety equipment installed in a railroad crossing;
A main processor unit for storing equipment operation information and failure information collected through the input device in real time, determining whether there is an abnormality in the crossing equipment based on the equipment operation information and the failure information, ;
An output device that transmits a failure of the information analyzing device to the control unit under the control of the main processor unit and transmits a driving signal to the ventilation fan;
An interface card for transmitting operation and failure information of the crossing equipment to a remote station operating system under control of the main processor unit; And
And a display device for visually displaying operation and failure information of the crossing equipment under the control of the main processor unit,
Wherein the first lightning strike protection unit protects the information analysis apparatus from lightning strikes by input and output of a power source and a communication line and the second lightning strike protection unit protects the information analysis apparatus from a lightning strike flowing into an input port. Crossing signal information analyzer.
The apparatus of claim 1, further comprising an automatic time correction device that receives standard time from a satellite and corrects the time in real time.
delete [2] The surge protector according to claim 1, wherein the first lightning strike protection unit comprises: a surge protector which removes an overvoltage input to an input power source and passes a primary surge; A first fuse that is automatically shut off to protect the device from surges when the current output from the surge protector is an overcurrent; A master power supply relay controller for outputting power supplied through the first fuse to the master power supply or for interrupting the master power supply when the first surge voltage is supplied from the surge protector; A master power LED indicator for indicating a master power supply state under the control of the master power relay controller; A power supply output unit for outputting power from the master power relay control unit; A third fuse for shutting off power when an overcurrent flows through the power supply output from the power output unit; And a power measuring unit for measuring a voltage level of a power source output through the third fuse.
[Claim 4] The system of claim 4, wherein the first lightning stroke circuit part includes: a second fuse for shutting off or supplying power including a surge output from the master power relay control part; A slave power supply delay control unit for delaying a power supply time through the second fuse; A slave power supply relay controller for supplying power through the second fuse to the power output unit as a slave power supply under the control of the slave power supply delay control unit; And a slave power LED indicator for indicating a slave power supply status under the control of the slave power relay controller.
The power supply unit according to claim 1, wherein the power supply unit comprises: a first fuse for blocking when an overcurrent flows into an input power source; A master DC / DC converter for converting the master power through the first fuse to a DC power of a predetermined level; An automatic switching unit for controlling the output of the power source and the power outputted from the master DC / DC converter or controlling the output of the slave power source; A second fuse for blocking when an overcurrent is included in the power supplied through the automatic transfer unit; A slave DC / DC converter for converting power from the second fuse to a predetermined DC power and supplying the power to the automatic switching unit via a slave power supply; A third fuse for shutting off power when an overcurrent is included in the power output from the automatic switching unit; A power measuring unit for measuring a level of power outputted through the third fuse; And a reset switch for resetting the automatic transfer unit.
7. The apparatus of claim 6, wherein the automatic switching unit comprises: a relay control unit for supplying the input power to a slave power supply; A power controller for selecting and supplying a master power or a slave power; A power LED display unit for indicating whether the power supplied according to the control of the power control unit is a master power or a slave power; A power error detection unit for detecting an error of the master power supply or the slave power supply; A voltage detector for detecting a voltage level of the master power supply or the slave power supply; An output power delay control unit for delaying the output power by a predetermined time; And a power output unit for outputting either the master power or the slave power to the power source under the control of the power control unit.
[2] The apparatus of claim 1, wherein the main processor unit comprises: a power supply for supplying driving power; A buffer for buffering equipment operation information and failure information collected through a bus; A central processing unit that stores collected information received through the buffer in a storage unit in real time and controls display and transmission of equipment operation status or failure information; A temperature sensor for detecting the temperature of the information analyzing apparatus and transmitting the detected temperature to the central processing unit; And a communication and information display interface device connected to the central processing unit to transmit output information or to display status information.

Images