KR102132363B1 - Rail-road-signal system controlling track switch and traffic light - Google Patents

Abstract

The present invention relates to a line changer. The line changer includes a conversion gauge, a conversion assembly, a plurality of measurement assemblies, and a control module. According to the present invention, pedestrians and vehicles can be protected from railroad vehicles.

Description

Railroad signaling device using track changer and signaler{RAIL-ROAD-SIGNAL SYSTEM CONTROLLING TRACK SWITCH AND TRAFFIC LIGHT}

The present invention relates to a railroad signaling device using a track converter and a signal to enable safe rail crossing while preventing collision with a railroad vehicle traveling in reverse.

An analysis of the major accidents in the world by Swiss SIC insurance companies over the course of the year (as of 1992) found that on average 0.8 cases per day resulted in 1,90 deaths. The number of accidents was the highest with 170 natural disasters (35.9%), 18.5% with 55 road and rail accidents, 14.4% with 43 water accidents, 11.7% with 35 large fires, and 9.4 with 28 air accidents. % Net was. However, more important than the number of accidents is how much human or property damage has occurred.

According to this data, the casualties caused by these major accidents (death) are after natural disasters caused by typhoons, floods, and earthquakes. It has been reported that two to four times as many accidents have occurred.

In particular, most of the train accidents are occurring in the backward countries, and the causes of the accidents are mostly train collisions and derailment accidents due to the failure of signaling devices. Due to the nature of rail traffic transporting a large number of passengers and cargo, safety accidents caused by failure of the signal security device can be a major human disaster, and can be a huge loss not only for individuals but also for the country.

Here, the railway signal security device means each device related to the safe operation of a vehicle, that is, a signal device, an interlocking device (interlocking with mechanical relays), an occluding device, an automatic control device for a train, etc. It worked systematically.

Among them, the track circuit device belonging to the electric relay interlock device is composed of a track circuit transmitter device, a bond, and a rail insulation, and it is used to detect a vehicle running on the track and post it to a certain section of the rail so that it cannot be switched to another track. It serves to create a circuit.

To this end, the track circuit device is largely composed of a power supply module, a transmitting device, a receiving device, and a relay. At this time, the conventional track circuit transmission device is an analog form of AC power input, so it was a device with a function of simply detecting the fuse state of the fuse, and there was a problem in that a terminal must be checked individually when a failure occurs.

In addition, the conventional track circuit transmission device communicates between the rail vehicle control assembly and the railroad vehicle through the wheel and the vehicle wheel in contact with each other, so if the contact between the railroad vehicle and the vehicle wheel is poor, communication between the transmitter installed on the track and the receiver installed on the rail vehicle It was cut off, and it was not possible to smoothly control the beacons of the rail vehicle pipe control assembly.

Prior Art Document 1. Patent Publication No. 10-2016-0109346 (published on September 21, 2016)

Accordingly, the present invention is to solve the above problems, and provides a railway signal device using a line changer and a beacon to protect pedestrians and vehicles crossing the railway from the railway vehicle while preventing collisions between railway vehicles reversely running on the same railway. Let the problem to be solved.

In order to achieve the above object, the present invention,

A transitional track that connects the tracks of different main tracks to change the running track of a railway vehicle,

A conversion assembly that opens or closes the conversion rail, so that the railroad car can enter the railroad rail with the conversion rail connected to the main rail rail,

The lower end of the inverted triangular shape is recessed in the internal groove leading to the front end portion and the front end portion of the first track. A heat-resistant sensing panel coated with a film; A knock sensor installed at a lower vertex of the lower end of the sensing panel to sense vibration and transmit a vibration signal; A piezoelectric sensor installed at the upper end of the sensing panel located at the front end of the first track to sense the pressurization of the railway vehicle wheel and transmit a pressurization signal; A heat-resistant finish substrate covering the upper end of the sensing panel, and a plurality of resistors are connected in parallel via a conductive synthetic resin line on the finish substrate, and an ammeter measures the current value for each synthetic resin line, respectively, and changes the current value for each ammeter. A plurality of detection modules comprising: a damage detector that a detector recognizes and transmits a recognition signal: In the first and second cycles arranged in line with each other, the first cycle prevents the vibration of the second cycle from being transmitted to the first cycle. Shock-absorbing panel of heat-resistant shock absorbing material installed on the rear end of the second wake facing the front end of the ledge: Detecting the vibration signal and the pressure signal and the recognition signal, respectively, to check the vibration size and pressure of the sensing panel, and to check whether the heat-resistant finish substrate is damaged. A detection system that checks and dataizes the detection information: a transmitter that sets and transmits an ID to the detection information, and comprises a plurality of measurement assemblies that are installed spaced apart from each other along a line, and

By comparing the detection information for each ID received from the measurement assembly with a standard value of vibration magnitude for each distance, the distance between the measurement assembly and the railway vehicle is predicted to generate prediction information, and the measurement assembly including the pressurized signal of the piezoelectric sensor The distance measurement module ignores the detection information for a certain period of time: controls the signal of the beacon according to the result information including the prediction information and the pressurized signal, but the first prediction information that is the distance between the first measurement assembly and the railway vehicle in a plurality of measurement assemblies. If the difference between the distance between the 2nd measurement assembly and the second measurement assembly is within the allowable range and the measured distance between the first measurement assembly and the second measurement assembly, the speed is calculated based on the distance change between the first or second measurement assembly and the railway vehicle. Control the signal of the signaler according to the prediction information, ignore the prediction information if it exceeds the allowable range, control the operation of the signaler according to the pressurized signal, and check the detection information of the recognition signal. Transmit assembly by sending an open control signal to the switching assembly located before the driving direction of the railroad cars by checking the distance change of the railroad cars through the above prediction information to check whether or not the railroad cars driving the same track are in reverse. A control module consisting of: a control module that opens the corresponding turning track to allow the railway vehicle to enter the turning track,

It is a railway signal device using a track converter and a signal device made of

The present invention, while preventing collisions between railroad cars traveling in reverse on the same railroad, protects pedestrians and vehicles crossing the railroad from the railroad cars, accurately grasps the traveling vibration of the railroad cars and enters the railroad cars into the protected area. It has the effect of enabling and controlling reliable railroad vehicles.

1 is a plan view schematically showing an installation state of a signal transmission device according to the present invention,
2 is a block diagram showing a signal communication structure between components configured in a signal transmission apparatus according to the present invention,
3 is a diagram schematically showing a state in which a track changer of a signal transmission apparatus according to the present invention changes a track by changing a track;
4 is a graph schematically showing the vibration status of the signal transmission apparatus according to the present invention,
5 is a perspective view showing a state in which the signal transmission apparatus according to the present invention is installed in an oscillator,
6 is a perspective view showing an exploded view of the first and second bins where the signal transmission apparatus according to the present invention is located,
7 is a view schematically showing an electrical connection between a control box and a sensor equipped with an ammeter, a transmitter, and a power supply of the signal transmission device according to the present invention,
8 is an exploded perspective view of the signal transmission device shown in FIG. 5,
9 is a perspective view showing a state in which the damage detector is installed on the detection panel of the signal transmission apparatus according to the present invention,
10 is a circuit diagram showing the circuit state of the damage detector,
11 is a view schematically showing a state in which a wheel of a railway vehicle passes through a piezoelectric sensor of a signal transmission device according to the present invention.

The above-described features and effects of the present invention will become apparent through the following detailed description in connection with the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains can easily implement the technical spirit of the present invention. There will be. The present invention can be applied to various changes and may have various forms, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, it is not intended to limit the present invention to a specific disclosure form, it should be understood to include all modifications, equivalents, or substitutes included in the spirit and scope of the present invention. Terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

1 is a plan view schematically showing a state of installation of a signal transmission device according to the present invention, FIG. 2 is a block diagram showing a signal communication structure between components configured in a signal transmission device according to the present invention, and FIG. 3 is a It is a diagram schematically showing a state in which a track diverter of a signal transmission apparatus according to the invention changes a track by changing the track.

1 to 3, the railway signal apparatus of the present embodiment includes measurement assemblies (1, 1') and measurement assemblies (1, 1') installed on the first to fourth tracks (10, 10', 12, 12'). 1 to 1') The first to third transitions connecting the pipe control assembly 2 that controls the operation of the beacon 30 and the first to fourth orbits 10, 10', 12, 12' It includes a first to fourth switching assembly (3a, 3b, 3c, 3d) which is a line changer for switching the line via the tracks (13, 14, 15). Here, the first to third conversion cycles 13, 14 and 15 alternately connect the first and second cycles 10 and 10' and the third and fourth cycles 12 and 12', respectively. Therefore, the railroad vehicle T driving on the first and second tracks 10 and 10' rides on the first and second tracks 13 and moves to the third and fourth tracks 12 and 12', and the third and fourth tracks The railway vehicle T driving on the trajectories 12 and 12' travels to the first and second trajectories 10 and 10' on the second converting trajectory 14, and the first and second trajectories 10 and 10 The railroad car (T) driving on') moves to the 3rd and 4th tracks (12, 12') on the 3rd conversion track (15). As a result, the railroad car T sequentially turns the first and second tracks 10 and 10' and the third and fourth tracks 12 and 12' through the first to third conversion tracks 13, 14, and 15. You can move and drive.

On the other hand, the railroad car T traveling on the first and second tracks 10 and 10' or the third and fourth tracks 12 and 12' is used for the first to third conversion tracks 13, 14 and 15. The first to fourth transition assemblies are at intersections between the first to fourth trajectories (10, 10', 12, 12') and the first to third transition trajectories (13, 14, 15) so that they can ride and move to different trajectories. (3a, 3b, 3c, 3d) are installed. Therefore, the first to fourth switching assemblies 3a, 3b, 3c, and 3d may operate in accordance with external control to maintain the current driving path of the railway vehicle or to change the driving path to another trajectory. For this, the first to fourth switching assemblies 3a, 3b, 3c, and 3d mechanically change the progress path of the first to third switching orbits 13, 14 and 15 according to the control signal of the control module 600 The switching device 31 to be configured, and the switching state confirmation module 32 to check the open and closed state of the switching device 31. Here, the'open' is a state in which the railway vehicle T is converted to change the driving direction to the first to fourth conversion assemblies 3a, 3b, 3c, 3d, and the'closed' is the railway vehicle T It is in a state of being stopped to maintain the first to fourth tracks 10, 10', 12, and 12' currently running without changing the driving direction. Therefore, when the first switching assembly 3a is closed, the railway vehicle T maintains a driving path along the first and second tracks 10 and 10', and when the first switching assembly 3a is open, the railway vehicle (T) rides on the first conversion track 13 and moves to the third and fourth tracks 12 and 12'.

On the other hand, the measurement assembly (1, 1') is installed on the rail, and includes a knock sensor 120, a piezoelectric sensor 130, a breakage detector 140, a detector 300 and a transmitter 400, knock The sensor 120, the piezoelectric sensor 130, the damage detector 140, the sensor 300 and the transmitter 400 will be described in more detail later.

A number of measurement assemblies (1, 1') are installed in the first to fourth orbits (10, 10', 12, 12') and communicate with the tube control assembly (2). Therefore, the position of the railroad cars T and T'traveling on the first to fourth tracks 10, 10', 12, and 12' is predicted by the pipe control assembly 2 to control the operation of the beacon 30. Of course, it checks the existence of the railroad cars T and T'that ride in the same tide and run in reverse.

In the case of this embodiment, as shown in Fig. 3 (a), two railway vehicles (T, T') driving the first track 10 are recognized by the measurement assembly (1, 1'), and the corresponding detection information is recognized. Transfer to the pipe control assembly (2). The control module 600 of the pipe control assembly 2 checks the predicted information of the distance measurement module 500 to confirm that the two railway vehicles T and T'are close and determines that it is reverse driving. To determine whether to drive in reverse, one of the two railroad cars (T, T') detected from one side of the measurement assembly (1, 1') is far from the measurement assembly (1, 1'), and the other is the measurement assembly. It is judged that the distance from (1, 1') is getting closer.

The control module 600 predicts the current position of the railway vehicle T determined to be reverse running, and transmits an open control signal to the first switching assembly 3a (see FIG. 3) located before the traveling direction of the railway vehicle T, , The switching device 31 of the first switching assembly 3a is driven so that the first switching 10 and the first switching 13 are connected to each other. Here, when the first switching assembly 3a and the third switching assembly 3c are identified in front of each of the railroad vehicles T and T'that run in reverse, the control is performed such that only one of the switching assemblies is driven. In this embodiment, only the first switching assembly 3a is driven.

Eventually, the railroad vehicle T traveling on the first track 10 moves to the third track 12 on the first conversion track 13 as shown in FIG. 3(b). The other railway vehicle T'driving in the reverse direction is driving while maintaining the path of the first track 10.

When the railway vehicle T moved to the second rail 12 passes through the third conversion assembly 3c capable of returning to the first rail 10, the control module 600 is shown in FIG. 3(c). As described above, the control vehicle for opening the second switching assembly 3b and the third switching assembly 3c transmits a control signal to the railroad car T located on the second rail 12 to ride the second rail 14. Control to return to the ark 10.

4 is a graph schematically showing the current state of vibration of the signal transmission device according to the present invention, FIG. 5 is a perspective view showing a state in which the signal transmission device according to the present invention is installed on an oscillator, and FIG. 6 is a signal according to the present invention It is a perspective view showing an exploded view of the first and second bins where the transmitting device is located, and FIG. 7 schematically illustrates the electrical connection between the control box and the sensor equipped with the ammeter and transmitter and power supply of the signal transmitting device according to the present invention. 8 is a perspective view illustrating an exploded view of the signal transmission device shown in FIG. 5.

1 to 8, the signal transmission apparatus of the present embodiment detects the IDs of the measurement assemblies 1 and 1'and the measurement assemblies 1 and 1'that detect vibrations of the railroad vehicle moving along the track. It is composed of a tube control assembly (2) for controlling the operation of the beacon (30) according to the information.

Here, the measurement assemblies (1, 1') are installed to be spaced apart at a specified distance along the line, and transmit their own detection information to the pipe control assembly (2). To this end, the measurement assembly (1, 1') is composed of a plurality of detection modules 100, a buffer panel 200, a sensor 300 and a transmitter 400.

The sensing module 100 is recessed in the internal groove 11 connected to the front end portion 11a and the front end portion 11b of the first track 10 supported by the sleeper 20, but the bottom portion 111 of an inverted triangular shape The heat-resistant sensing panel 110 protruding downward of the first track (10); A knock sensor 120 installed on the lower part 111 of the sensing panel 110 to sense vibration and transmit a vibration signal; A piezoelectric sensor 130 installed at the upper end 112 of the sensing panel 110 located at the upper end portion 11b of the first track 10 to sense the pressurization of the railway vehicle wheel and transmit a pressurization signal; A heat-resistant finish substrate 141 covering the upper part 112 of the sensing panel 110, and a plurality of resistors 142 are connected in parallel via a conductive synthetic resin line on the finish substrate 141, and an ammeter 143 is the synthetic resin. It consists of a; breaker detector 140 that measures the current value for each line and detects a change in the current value for each ammeter 143 and transmits a recognition signal.

In more detail, as shown in FIGS. 5 and 8, the sensing panel 110 is arranged to be disposed between the first and second tracks 10 and 10' arranged in line with each other. ) Is installed on the front end portion 11a of the first track 10 facing the. In the present embodiment, the first track 10 is formed with an internal groove 11 in a section leading to the front end portion 11a and the upper front end portion 11b, and the sensing panel 110 is formed to be inserted into the internal groove 11 And installed. Since the sensing panel 110 is formed to correspond to the internal groove 11, the sensing panel 110 is closely recessed in the internal groove 11, thereby allowing the sensing panel 110 to have a front end portion (1) of the first track 10. 11a) and the top end portion 11b is installed without protruding. On the other hand, the lower end 111 of the sensing panel 110 forms an inverted triangular shape and protrudes downwardly of the first tank 10 and has heat resistance to maintain the heating of the first tank 10 without deformation. As a result, the sensing panel 110 maintains a close contact with the first track 10, and through this, the vibration of the crab 1 track 10 is transmitted to the sensing panel 110 as it is. For reference, the sensing panel 110 may be applied to a heat-resistant material such as aromatic polyamide, polyimide, polysulfone, polyimidasolpyrrololone, polybenzoimidazole, polyphenylene oxide.

On the other hand, the sensing panel 110 in the recessed groove 11, the entire back surface to maintain the state in close contact with the front end portion (11a) and the top end portion (11b) of the first track (10) The Alnico magnetic film 113 is coated. The AlNiCo magnetic film 113 is adhered to the first track 10, which is a magnetization material, with strong magnetic force, thereby fixing the entire rear surface of the sensing panel 110 without separation from the first track 10. Of course, the sensing panel 110 and the first track 10 are primarily fixed by an adhesive or a separate fastening member (not shown), but the adhesive or fastening member in a vibration and heating environment over a long period of time is the sensing panel 110 ) And the fastening force between the first track 10 is lost. Therefore, in order to maintain the adhesion between the sensing panel 110 and the first track 10, the AlNiCo magnetic film 113 is reinforced on the back surface of the sensing panel 110, so that the back surface of the sensing panel 110 is the first track ( 10) is maintained in close contact, and through this, the vibration of the first tank 10 is transmitted to the sensing panel 110 as it is.

The knock sensor 120 is installed on the lower end 111 of the sensing panel 110 to detect vibration and transmit a vibration signal. Since the lower part 111 of the sensing panel 110 maintains a protruding state below the first track 10 as shown in FIG. 7, the lower part 111 with relatively free movement is a part installed in the first track 10 The vibration of the first oscillation 10 is effectively sensed because the knock sensor 120 is located at the lower vertex of the inverted triangle where the vibration is concentrated at the lower end 111.

The piezoelectric sensor 130 is installed at the upper end 112 of the sensing panel 110 located at the upper end portion 11b of the first track 10 to sense the pressurization of the railway vehicle wheels and transmit a pressurization signal. Since the wheels of the railroad car moving on the track move on the first and second tracks 10 and 10', the piezoelectric sensor 130 receives a relatively strong pressure when the wheels of the railroad car pass. Therefore, the piezoelectric sensor 130 generates a designated electric signal and transmits it as a pressurized signal.

The damage detector 140, a heat-resistant finish substrate 141 covering the upper part 112 of the sensing panel 110, and a plurality of resistors 142 are connected in parallel via a conductive synthetic resin line on the finish substrate 141 An ammeter 143 measures the current value for each synthetic resin line, and the detector 144 recognizes a change in the current value for each ammeter 143 and transmits a recognition signal. The first and second tracks 10 and 10' used for a long time generate wear, and through this, the upper part 112 of the sensing panel 110 is exposed to the outside. The exposed sensing panel 110 and the piezoelectric sensor 130 are subjected to a weight exceeding a limit from the wheels of the railway vehicle, which causes damage to the sensing panel 110 and the piezoelectric sensor 130. The damage detector 140 is self-damaged when it receives a load at this point and transmits a recognition signal. Eventually, the manager proceeds with the subsequent maintenance processing according to the recognition signal. The configuration of the damage detector 140 will be described in more detail below.

The buffer panel 200 is the first orifice 10 so that the vibrations of the second orifice 10' are not transmitted to the first orifice 10 in the first orifice 10 and the second orifice 10' arranged in line with each other. It is installed on the rear end face portion of the second track 10' facing the front end face portion 11a of (10). The cushioning panel 200 forms a cushioning material for vibration damping, and has heat resistance in response to the heat of the second tank 10'. Vibration detection should be avoided in the measurement assembly (1, 1') at the point where the railway vehicle passed. This is because it is necessary to prevent the vibration of the railway vehicle passing through as the vibration of the subsequent railway vehicle. Therefore, the buffer panel 200 is disposed between the first and second tracks 10', and the vibrations are sharply reduced at the boundaries of the first and second tracks 10 and 10'. That is, the vibration caused by the subsequent railroad vehicle rises rapidly as it passes through the trajectory, and the vibration after passing through the measurement assembly (1, 1') rapidly decreases as it passes through the railroad track. It is easy to distinguish vibrations from the vehicle.

The sensing system 300 detects each of the vibration signal, the pressure signal, and the recognition signal, checks the vibration size and pressure of the sensing panel 110, and checks whether the heat-resistant finish substrate 141 is damaged and dataizes the detection information. Since the vibration signal of the knock sensor 120, the pressure signal of the piezoelectric sensor 130, and the recognition signal of the damage sensor 140 are both electrical signals, the sensor 300 transmits the vibration signal, the pressure signal, and the recognition signal to the specified process. Analyze and data accordingly. As an example, the vibration signal transmits a vibration signal, which is an electrical signal of a specified size, as the size of the vibration sensed by the knock sensor 120 increases, so the detection system 300 adjusts the vibration size according to the vibration signal. Recognize and dataize. In addition, since the subscription signal is transmitted by the piezoelectric sensor 130 pressurized above a reference value, the sensor 300 recognizes and dataizes the pressure of the wheel according to the corresponding pressurization signal. In addition, since the damage signal 140 is transmitted when the state of damage above the specified reference value is confirmed, the detection system 300 recognizes the risk of damage to the sensing panel 110 or the piezoelectric sensor 130 according to the corresponding recognition signal. Data.

The transmitter 400 sets and transmits an ID to the detection information. The detection information transmitted by the transmitter 400 is transmitted to the pipe control assembly 2, in which case the measurement assembly 1, 1'and the pipe control assembly 2 are connected to a cable ( Wire communication is performed through C).

For reference, the sensing system 300 and the transmitter 400 are built in and protected in a separate case B, and operate by receiving power from a power source P installed in the case B. At this time, the power source P may be a power supply method that receives and processes power from the outside, or may be an independent battery.

The pipe control assembly 2 analyzes the detection information transmitted from the plurality of measurement assemblies 1 and 1'according to a designated process and proceeds with subsequent processing. To this end, the pipe control assembly 2 calculates the distance between the measurement assembly 1 and 1'and the railway vehicle, filters the received vibration, and generates a distance measurement module 500 and a distance measurement module 500. It consists of a control module 600 for controlling the operation of the signal signal 30 and the line switcher (3a, 3b, 3c, 3d) according to the result information.

To explain the configuration in more detail, the distance measurement module 500 compares the detection information for each ID received from the measurement assembly 1, 1'with the standard value of the vibration magnitude for each distance, and measures the measurement assembly 1, 1'. ) And predicts the distance between railway cars to generate prediction information. As described above, since the detection information of the measurement assembly is a data of the size of the vibration signal, the distance measurement module 500 can check the size of the vibration signal through the detection information, and the distance according to the size (vibration size) of the vibration signal. Based on the set standard value, the distance between the measurement assembly (1, 1') and the railway vehicle that caused the vibration can be predicted. Eventually, the distance measurement module 500 predicts the countdown of the distance between the measurement assembly (1, 1') and the railway vehicle according to the detection information received in real time from the measurement assembly (1, 1'), and the control module ( 600) checks the operation control timing of the beacon 30 according to the distance from the railway vehicle.

On the other hand, when the distance measurement module 500 checks the detection information for the pressure signal of the piezoelectric sensor 130, the detection information for the vibration signal of the measurement assembly (1, 1') transmitting the pressure signal is ignored. That is, since the transmission of the pressurized signal means that the railway vehicle passes through the measurement assembly (1, 1'), the detection information of the vibration signal for predicting the distance from the measurement assembly (1, 1') is unnecessary. to be. In addition, after confirming the detection information of the pressurized signal, a relatively large vibration signal is confirmed for a certain period of time. Since this is a vibration signal caused by the railway vehicle passing through the measurement assembly 1, 1', the corresponding vibration signal is extinguished. For a certain period of time, the detection information of the vibration signal is ignored. When the detection information for gradually increasing the vibration signal after the predetermined time is confirmed, it is recognized that it is the approach of a subsequent railway vehicle, pays attention to the vibration signal, and generates the prediction information.

The control module 600 controls the signal of the signal device 30 according to the prediction information and the result information including the pressurized signal. As described above, since the prediction information is the distance between the measurement assembly 1 and 1'and the railroad vehicle, if it is determined that the predicted distance is a required distance of the operation of the beacon 30, the control module 600 displays the beacon 30 ). In addition, when the result information on the subscription signal is confirmed, the control module 600 checks the position of the measurement assembly (1, 1') where the current railroad car is located, and if it is determined that the signal 30 is the required distance, control The module 600 controls the signaler 30.

In addition, the control module 600 checks whether or not the railroad cars T and T'run in the same track based on the prediction information of the measurement assemblies 1 and 1'. As a result of checking, when checking the reverse driving of the railroad cars T and T', the control module 600 checks the position of the railroad cars T and T'and transfers them to the corresponding conversion assemblies 3a, 3b, 3c, and 3d. Send a control signal. The conversion assembly (3a, 3b, 3c, 3d) receiving the control signal performs the opening and closing as described above, through which the railway vehicle (T, T') changes the track as shown in Fig. 3 and crashes. prevent.

Control of the switching assembly 3a, 3b, 3c, 3d of the control module 600 has been described above, so a detailed description thereof will be omitted.

On the other hand, a plurality of measurement assemblies (1, 1') are installed, and each measurement assembly (1, 1') transmits detection information independent of each other. Therefore, the control module 600 receives different detection information from the measurement assembly 1, 1', and predicts the distance between the first measurement assembly 1 and the railway vehicle, and predicts the distance between the second measurement assembly 1'and the railway vehicle. Respectively. At this time, since the measured distance between the first measurement assembly 1 and the second measurement assembly 1'was set in the control module 600, the predicted distance between the first measurement assembly 1 and the railway vehicle, and the second measurement assembly 1' If the difference in the predicted distance between railway vehicles is within the allowable range and the measured distance, the control module 600 controls the operation of the beacon 30 based on the predicted information. However, if the difference between the measured distance and the predicted distance exceeds the allowable range, the control module 600 ignores the predicted information and controls the operation of the signaler 30 according to the detection information of the pressurized signal. Also, the standard value is corrected.

On the other hand, when the control module 600 confirms the detection information of the recognition signal, it transmits the location and warning information of the corresponding measurement assembly (1, 1'). The recognition signal notifies the breakage of the measurement assembly (1, 1') and the breakage and aging state of the trajectory where the measurement assembly (1, 1') is installed, so the control module (600) warns information to notify the administrator. Is to send

9 is a perspective view showing a state in which a damage detector is installed on a detection panel of a signal transmission apparatus according to the present invention, FIG. 10 is a circuit diagram showing a circuit state of the damage detector, and FIG. 11 is a wheel of a railway vehicle viewed It is a diagram schematically showing a state via a piezoelectric sensor of the signal transmission device according to the invention.

9 to 11, the damage detector 140 of the present embodiment is a heat resistant finish substrate 141 covering the upper part 112 of the sensing panel 110, and a plurality of resistors 142, the finish substrate 141 Phases are connected in parallel via a conductive synthetic resin line, and the ammeter 143 measures the current value for each synthetic resin line, and the detector 144 recognizes a change in the current value for each ammeter 143 and transmits a recognition signal. Here, the finishing substrate 141 is a reinforced plastic material, but is damaged when pressed over a certain amount. Therefore, when the heavy-duty railway vehicle wheel R passes through and presses the finishing substrate 141 with an impact of a predetermined value or more, the finishing substrate 141 is damaged. At this time, since the conductive synthetic resin line functioning as the energizing line is applied to the finishing substrate 141 and cured, it can be broken and separated together when the finishing substrate 141 is damaged, which is a cause of increasing the resistance value soon. .

Meanwhile, since the plurality of resistors 142 arranged in parallel with each other have the same resistance value, the current values applied to each resistor 142 are also constant. However, when a space is generated through the breakage of the synthetic resin line, since the resistance value of the synthetic resin line increases, the current value of the synthetic resin line sensed by the ammeter 143 becomes smaller than the current value of the other synthetic resin line. As a result, as the number of synthetic resin lines to be damaged increases, the magnitude of the current value sensed by the detector 144 decreases. Therefore, when the current value decreases below the reference value, the detector 144 regards the damage detector 140 as a failure and recognizes the recognition signal. To send.

In the detailed description of the present invention described above, with reference to the preferred embodiments of the present invention, those skilled in the art or those skilled in the art will appreciate the spirit of the present invention described in the claims to be described later And it will be understood that various modifications and changes of the present invention can be made without departing from the technical field.

1, 1'; Measurement assembly 2; Pipe control assembly 10; First track
10'; Second track 30; semaphore
100; Detection module 110; Sensing panel 120; Knock sensor
130; Piezoelectric sensor 140; Damage detector 200; Buffer panel
300; Sensor 400; Transmitter 500; Distance measurement module
600; Control module

Claims (1)

A transitional track that connects the tracks of different main tracks to change the running track of a railway vehicle,
A conversion assembly that opens or closes the conversion rail, so that the railroad car can enter the railroad link with the conversion rail connected to the main rail track.
The lower end of the inverted triangular shape is recessed in the internal groove leading to the front end portion and the front end portion of the first track. A heat-resistant sensing panel coated with a film; A knock sensor installed at a lower vertex of the lower end of the sensing panel to sense vibration and transmit a vibration signal; A piezoelectric sensor installed at the upper end of the sensing panel located at the front end of the first track to sense the pressurization of the railway vehicle wheel and transmit a pressurization signal; A heat-resistant finish substrate covering the upper end of the sensing panel, and a plurality of resistors are connected in parallel via a conductive synthetic resin line on the finish substrate, and an ammeter measures the current value for each synthetic resin line, respectively, and changes the current value for each ammeter. A plurality of detection modules comprising: a damage detector that a detector recognizes and transmits a recognition signal: In the first and second cycles arranged in line with each other, the first cycle prevents the vibration of the second cycle from being transmitted to the first cycle. Shock-absorbing panel of heat-resistant cushioning material installed on the rear end of the second tank facing the front end of the rim: Detecting the vibration signal, the pressure signal and the recognition signal, respectively, to check the vibration size and pressure of the sensing panel and to check whether the heat-resistant finish substrate is damaged A detection system that checks and dataizes the detection information: a transmitter that sets and transmits an ID to the detection information, and includes a plurality of measurement assemblies installed apart from each other along a line, and
By comparing the detection information for each ID received from the measurement assembly with a standard value of vibration magnitude for each distance, the distance between the measurement assembly and the railway vehicle is predicted to generate prediction information, and the measurement assembly including the pressurized signal of the piezoelectric sensor The distance measurement module ignores the detection information for a certain period of time: controls the signal of the beacon according to the result information including the prediction information and the pressurized signal, but the first prediction information that is the distance between the first measurement assembly and the railway vehicle in a plurality of measurement assemblies. If the difference between the distance between the second measurement assembly and the second measurement assembly is within the allowable range and the measured distance between the first measurement assembly and the second measurement assembly, the speed is calculated based on the distance change between the first or second measurement assembly and the railway vehicle. Control the signal of the beacon according to the predictive information, ignore the predictive information if it exceeds the allowable range, control the beacon according to the pressurized signal, and check the detection information of the cognitive signal. Transmit assembly by sending an open control signal to the switching assembly located before the driving direction of the railroad cars by checking the distance change of the railroad cars through the prediction information to check whether or not the railroad cars driving the same track are reversed. A control module consisting of: a control module that opens the corresponding turning track to allow the railway vehicle to enter the turning track,
Railroad signal device using a track converter and signal, characterized in that consisting of.

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