JP3201938U - Train stop system - Google Patents

Abstract

The present invention provides a train stop system for construction that can save labor for installation, removal, and movement. A train stop system 100 installed at a construction site along a railroad track, which is arranged along the railroad track, an upstream side alarm output device 3, a plurality of warning command devices 4a to 4c, and a downstream side Side alarm output device 5, alarm command devices 4 a to 4 c are an input unit to which a warning command is input by a construction worker, and a first communication unit that transmits alarm signal data generated by the input of the warning command The upstream alarm output device 3 and the downstream alarm output device 5 include alarm devices 6a and 16a, a second communication unit that receives the transmitted alarm signal data, and an alarm based on the received alarm signal data. And a controller for operating the devices 6a and 16a. [Selection] Figure 1

Description

  The present invention relates to a train stop system for a construction worker who works on or around a railway track to issue an alarm to a train approaching a construction site.

  Conventionally, when construction is performed on or around a railroad track, it has been obliged to install a train stop system that issues a warning for stopping trains that are about to enter the construction site unexpectedly. Such a train stop system, for example, arranges light emitters in each of the upward and downward directions of the railway track, and the construction worker presses a switch having a push button installed on the construction site, thereby moving the upward and downward directions. It was like lighting a direction light emitter to alert the train driver to stop.

  Construction on or around the railroad tracks had to be done quickly when there was no train operation. In addition, since the construction site along the railroad track has a relatively long distance, the distance between the start point and the end point is relatively long.

  In the conventional train stop system for construction, the light emitting devices in the upward and downward directions and the switch equipment having the push button are connected by an electric cable, and the relay of the power control device is closed by energizing by pressing the switch. In general, the power supply is connected to a power source connected to the light emitter. For example, the following Patent Document 1 includes a down signal light emitter, an up signal light emitter, and an alarm buzzer. In a construction train stop device that selectively connects a power source to the light emitter and the alarm buzzer via a control unit, A separate first driving path from the power source to the downstream signal light emitter, the upstream signal light emitter, and the alarm buzzer is formed, and the downstream signal light emitter and the upstream signal light emitter are transmitted from the power source via the first driving path of the alarm buzzer. The construction train stop device in which each of the different second drive paths leading to is formed is disclosed.

JP 2002-53042 A

  A conventional train stop system for construction as disclosed in Patent Document 1 includes an ascending and descending light emitter, an alarm command device having a push button, and a control unit that gives a power supply instruction to a power source connected to the light emitter. Etc. were connected by electric cables. Since the electric cable has a large diameter, the conventional train stop system is heavy and very bulky. Therefore, it took a lot of labor and time to install and remove the train stop system including the laying of electric cables. Moreover, in the construction on or around the railway track, the construction of the entire section may be completed while moving the entire construction section little by little. In such a case, when a conventional train stop system is used, it takes a lot of labor and time to move each section.

  Moreover, since the conventional train stop system for construction was connected with an electric cable, there was only a method for conducting a disconnection test by supplying electricity to the electric cable in order to confirm the presence or absence of the disconnection portion. Since it is difficult to conduct the disconnection test by supplying electricity to the electric cable, it was difficult to do it many times during the operation of the train stop system. . Therefore, after confirming only once before the start of construction, even if the electric cable is cut due to an unexpected situation, it could not be detected.

  In order to solve the problems of the conventional train stop system for construction as described above, the present invention can save labor for installation, removal, and movement, and can detect disconnection while operating. The purpose is to provide a train stop system.

  One aspect of the present invention is a train stop system installed at a construction site along a railway track, from the local area network (LAN) built in the construction site and from the beginning of the construction site along the railway track. 1st alarm output device arranged in order, and at least 1 alarm command device arranged at intervals mutually, connected to LAN, the 1st alarm output device becomes a server, and alarm command device is The first alarm output device is a client, and includes a first alarm device, a first control unit, and a first communication unit. The alarm command device is an input for inputting a warning command by a construction worker. A second control unit that generates an alarm request when an alarm command is input, and a second communication unit, wherein the first communication unit receives the alarm request from the second communication unit. Output to the first control unit, the first control unit is an alarm request A first construction for a train stop system for operating the alarm device based. According to such a train stop system, at least one alarm command device and the first alarm output device transmit the alarm request by transmitting and receiving the alarm request via communication via the LAN. The alarm request can be transmitted via a light, thin cable such as an optical cable or a LAN cable without being necessary. Therefore, labor saving of work such as installation, removal, and movement of the train stop system can be achieved.

  The train stop system includes a plurality of alarm command devices having different identification information, and the server specifies the identification information of the alarm command device that is the source of the alarm command, and other alarm command devices other than the source It is preferable to give identification information to. In addition, it is preferable that the other alarm command device further includes a display unit that displays to identify the source alarm command device when the identification information is given from the server. According to such a configuration, for example, by displaying a display for identifying a source alarm command device on a display unit or the like provided in another alarm command device, the location where the alarm command is issued It becomes possible to recognize even from an alarm command device away from the remote control. Furthermore, it is preferable that the warning command device further includes a notification unit that issues a warning when identification information is given from the server. According to such a configuration, for example, when an alarm command is issued from the source alarm command device, an alarm can also be issued in the vicinity of the alarm command device remote from the source.

  The train stop system is further provided with a second alarm output device serving as a client, which is disposed at the end of the construction site and includes a second alarm device, a third control unit, and a third communication unit. The third communication unit preferably receives an alarm request from the first communication unit and outputs the alarm request to the third control unit, and the third control unit preferably activates the second alarm device based on the alarm request. . According to such a configuration, an alarm can be issued to both the upstream and downstream ends.

  Moreover, it is preferable that the alarm command device further includes a notification unit that issues a disconnection alarm when communication is interrupted for a certain time or longer. Thus, since a disconnection alarm is issued when communication is interrupted for a certain period of time, a disconnection can be detected during operation.

  In addition, the LAN (Local Area Network) is appropriately selected from a wireless type and a wired type in consideration of the radio wave condition at the construction site and the ease of cable laying. It is particularly preferable to have at least one wireless access point for wirelessly communicating with the above-mentioned alarm output device or at least one alarm commanding device because installation and removal are easier.

  Moreover, it is preferable that a 1st alarm output device, a 2nd alarm output device, or at least 1 alarm instruction device is equipped with the battery connected to the solar panel generated with sunlight as a power supply. When the battery connected to such a solar panel that generates electricity by sunlight is used as the power source, it is preferable from the viewpoint that the power source can be secured without a permanent power source and can be always charged during operation.

  According to the present invention, it is possible to realize a train stop system for construction that can save labor for installation, removal, and movement.

FIG. 1 is an explanatory diagram showing the overall configuration of the train stop system 100. FIG. 2 shows a configuration block diagram of the first alarm output device 3. FIG. 3 shows a configuration block diagram of the alarm command device 4. FIG. 4 shows a configuration block diagram of the second alarm output device 5. FIG. 5 is a flowchart illustrating a procedure for establishing communication of the train stop system 100. FIG. 6 shows a flowchart of an example of a procedure of alarm command processing by the alarm command device 4. FIG. 7 shows a flowchart of an example of a procedure of alarm output processing by the first alarm output device 3. FIG. 8 shows a flowchart of an example of a procedure of alarm display processing by the alarm command device 4. FIG. 9 shows a flowchart of an example of a procedure of alarm output processing by the second alarm output device 5. FIG. 10 is a schematic explanatory diagram showing the overall configuration of the train stop system 200 using wireless communication. FIG. 11 is a schematic explanatory diagram showing an overall configuration of a train stop system 300 using a LAN cable.

  An embodiment of a train stop system according to the present invention will be described with reference to the drawings.

  FIG. 1 is an explanatory diagram illustrating an overall configuration of a train stop system 100 according to an embodiment. In FIG. 1, 1 is a LAN network trunk, 2a to 2e are LAN access points, 3 is a first alarm output device, 4a to 4c are alarm command devices, 5 is a second alarm output device, 6a, Reference numeral 16a denotes a light emitting device that is an alarm, 7a and 7b are power supply devices, and 7c is a solar panel connected to a battery 7a that is a power supply device. T1 and T2 are trains, and R is a track. Further, the left side direction of the paper is the up direction, and the right side direction of the paper is the down direction. Further, a construction site C is a portion surrounded by a rectangular broken line. The first alarm output device 3, the alarm command devices 4a to 4c, and the second alarm output device 5 are arranged at predetermined intervals in order from the start side to the end side of the construction site. P is a construction worker. The alarm command devices 4a to 4c are the same device, but are assigned ID1 to ID3, which are different identification IDs.

  2 is a first alarm output device 3 arranged on the upstream side, FIG. 3 is a block diagram of the configuration of the alarm command devices 4a to 4c (these are collectively referred to as the alarm command device 4), and FIG. 4 is arranged on the downstream side. It is a block diagram of the configuration of the second alarm output device 5 made.

  As shown in FIG. 2, the first alarm output device 3 includes a first communication unit 33, a first microcomputer 32, and a power supply control unit 38 that controls power supply to the light emitter 6a. The first communication unit is appropriately selected depending on the LAN network connection method, and examples thereof include a wireless Ethernet device and a wired Ethernet device. Moreover, the display part 34 and the speaker 35b are provided. The first alarm output device 3 has a server function for controlling communication of a network connected to the LAN. The first microcomputer 32 includes a server memory (not shown) for configuring the server, a program memory 32a in which a program of a first control unit 32d for performing predetermined processing described later is incorporated, a CPU 32b as a processor, data And a memory 32c. The first alarm output device 3 is connected to a battery 7a as a power supply device for supplying high voltage power to the light emitter 6a. The battery 7a may be connected to a solar panel 7c that generates electricity by sunlight that charges the battery 7a even during operation of the system. The power supply control unit 38 controls power supply to the light emitter 6a by the battery 7a. In addition, a power supply device is not restricted to a battery, You may use a permanent power supply.

  As shown in FIG. 3, the alarm command device 4 includes an input unit 41, a second microcomputer 42, a second communication unit 43, a display unit 44, a speaker 45a, a display lamp 45b, and a buzzer. 45c, an ID setting unit 46, and an output power control unit 47. The alarm command device 4 is connected to a battery 7b. The alarm command device 4 has a client function that is controlled by the server of the first alarm output device 3. The alarm command device 4 is supplied with electric power from a battery 7b which is a power supply device. The output power controller 47 controls power supply to the display lamp 45b and the buzzer 45c.

  The input unit 41 includes an emergency push button 41a that receives a warning command when pressed by a construction worker when it is determined that a warning should be issued, and a release push button 41b for releasing the emergency push button 41a. The emergency push button 41a is connected to an electrical switch (not shown), and when the emergency push button 41a is pressed, the electrical switch (not shown) passes an electric current as a warning request signal. The alarm request signal is converted into alarm request data by an unillustrated A / D converter incorporated in the input unit 41. The speaker 45a emits a beep sound or the like until the alarm command is canceled so that it can be confirmed that the emergency push button 41a has been pressed.

  The second microcomputer 42 includes a program memory 42a in which a client application (not shown) for configuring a client and a program of the second control unit 42d are incorporated, a CPU 42b as a processor, and a data memory 42c.

  The ID setting unit 46 is a setting switch such as a dip switch for assigning different identification IDs for distinguishing the alarm command devices 4a to 4c. The alarm command devices 4a to 4c in which different identification IDs ID1 to ID3 are set by the ID setting unit 46 are given addresses as different identification information on the network. The given address is stored in the data memory 42c.

  The second communication unit 43 of the alarm command device 4 having the client function is generated by the second control unit 42d at regular intervals with respect to the first communication unit 33 of the first alarm output device 3 having the server. First data to be transmitted and second data to be described later are transmitted and received. The first data includes the address of the sender identification information as header information, and includes an alarm request when an alarm command is input.

  When the other alarm command device 4 detects that an alarm command has been issued from any of the alarm command devices 4, the second control unit 42d generates a buzzer sound from the buzzer 45c and lights the display lamp 45b. By doing so, it is displayed that an alarm command has been issued from any of the alarm command devices 4. Further, the identification ID of the alarm command generation source is displayed on the display unit 44. In this way, an alarm command can be issued by displaying a display identifying the alarm command device of the transmission source on a display unit provided in another alarm command device or the like, and by turning on a buzzer or a display lamp serving as an alarm. It is possible to make a construction worker recognize the specified location even from an alarm command device away from the transmission source.

  As shown in FIG. 4, the second alarm output device 5 includes a third communication unit 53, a third microcomputer 52, and a power supply control unit 58 that controls power supply to the light emitter 16a. The second alarm output device 5 includes a client function controlled by the server of the first alarm output device 3. The third microcomputer 52 includes a program memory 52a in which a client application (not shown) for configuring a client and a program of a third control unit 52d for performing predetermined processing to be described later is incorporated, a CPU 52b as a processor, data And a memory 52c. The second alarm output device 5 is connected to a battery 7a as a power supply device for supplying high voltage power to the light emitter 16a. Connected to the battery 7a is a solar panel 7c that generates electricity by sunlight that charges the battery 7a even during operation of the system. The power supply control unit 58 controls power supply to the light emitter 16a by the battery 7a. In addition, a power supply device is not restricted to a battery, You may use a permanent power supply.

  Next, the operation of the train stop system 100 will be described. In operation of the train stop system 100, first, in order to establish network communication of the train stop system 100 installed at the construction site C as shown in FIG. The device 5 and the alarm command devices 4a to 4c are installed in the construction site along the railway line, and each device is activated, thereby causing them to belong to the LAN constructed in the construction site. FIG. 5 is a flowchart illustrating a procedure for establishing network communication of the train stop system 100.

  In the train stop system 100, first, for example, as shown in FIG. 1, the LAN network trunk line 1 and the plurality of access points 2a to 2e are installed in the construction site. 1 alarm output device 3, alarm command devices 4a to 4c, and second alarm output device 5 are arranged (step 1: s1). Here, in the present embodiment, an example in which three alarm command devices 4 are installed and a second alarm output device 5 is installed is shown. However, the train stop system is a single server serving as a server. A configuration comprising one alarm output device 3 and one alarm command device 4 serving as a client can be operated as a minimum configuration. In this case, the first alarm output device 3 is disposed only in one of the upward direction and the downward direction, and one alarm command device 4 is disposed at a location away from the first alarm output device 3. It becomes the composition like this. Moreover, although the example which installed the three warning instruction devices 4 was shown, the number of the warning instruction devices 4 can also be changed suitably.

  The first alarm output device 3 has a server function for controlling network communication of the system. The second alarm output device 5 and the alarm command devices 4a to 4c have a client function. Therefore, in order to make each device belong to the network, first, the first alarm output device 3 is activated (s2), and then the alarm command device 4 (4a to 4c) and the second alarm output device 5 are activated. Start (s3). Various devices are activated in this order to establish network communication of the train stop system 100. And establishment of communication of the train stop system 100 confirms establishment of communication between the 1st warning output device 3 which is a server, the 2nd warning output device 5 which is a client, and the warning instruction devices 4a-4c. (S4). In this way, the operation of the train stop system 100 is started.

  Next, after establishing communication between the first alarm output device 3 as a server and the second alarm output device 5 and the alarm command devices 4a to 4c as clients, the train stop system 100 is operated. Next, the processing of each device on the network when an alarm command is issued to a train approaching by a track construction worker will be described. 6 is an alarm command process by the alarm command device 4, FIG. 7 is an alarm output process by the first alarm output device 3, FIG. 8 is an alarm display process by the alarm command device 4, and FIG. 9 is by the second alarm output device 5. It is a flowchart which shows the flow of an alarm output process.

  After the train stop system 100 is activated, in the alarm command device 4, the second microcomputer 42 waits for an alarm command input from the input unit 41 as shown in FIG. 6 (s41). Then, when it becomes necessary to issue an alarm to the train approached by the construction worker, the construction worker approaches the nearest alarm instruction device 4 among the alarm instruction devices 4a to 4c, and the alarm is issued. The emergency push button 41a of the input unit 41 of the command devices 4a to 4c is pushed. In this embodiment, as shown in FIG. 1, it is assumed that the emergency push button 41a of the warning command device 4b is pushed by the construction worker P.

  When the construction operator P pushes the emergency push button 41a of the warning command device 4b, a warning command is input. The alarm command is converted from an electric signal to a digital signal by the A / D converter of the input unit 41 and transmitted to the second control unit 42d. When the second control unit 42d detects the input of the alarm command digital signal (s42), the second control unit 42d generates data including the alarm request and includes the data in the first data (s43). The first data including the alarm request has the address of the sender identification information as header information. Then, the first data including the alarm request is transmitted to the second communication unit 43 (s44). When the second microcomputer 42 does not detect the input of the alarm command, it always waits for detection of the input of the alarm command (s42).

  Then, the first data including the alarm request is transmitted from the second communication unit 43 to the first communication unit 33 of the first alarm output device 3 via the network (s45).

  Note that the second microcomputer 42 of each of the alarm command devices 4a to 4c sends the first data not including the alarm request to the first control unit 32d of the server at regular intervals even when the input of the alarm command is not detected. Send sequentially. The transmission of the first data is communication for each of the alarm command devices 4a to 4c to request the second data including information updated from the server at a predetermined timing, and the second control unit 42d When the first data is transmitted, it waits for reception of the second data as a response from the server at a predetermined timing after the transmission. The reception of the second data from the server in response to the transmission of the first data at regular intervals is used for confirming the disconnection of the network. That is, when the second data is not received at a predetermined time after the transmission of the first data, that is, when communication is interrupted for a certain time or longer, the second control unit 42d causes the alarm command device 4 to be disconnected from the network. A disconnection is recognized, a buzzer sound is generated from the buzzer 45c as a disconnection alarm, and the display lamp 45b is lit as an alarm for informing the disconnection.

  The second communication unit 43 of the alarm instruction devices 4a to 4c transmits the first data including or not including the alarm request to the access points 2b to 2c, respectively. Then, each first data is transmitted via the network trunk line 1 to the access point 2a to which the first alarm output device 3 is connected. The first data that has reached the access point 2 a is transmitted from the access point 2 a to the first communication unit 33 of the first alarm output device 3.

  In the first alarm output device 3, as shown in FIG. 7, the first communication unit 33 receives first data sequentially transmitted from the alarm command devices 4a to 4c (s30). Then, the first communication unit 33 transmits the first data to the first control unit 32d (s31). Then, the first control unit 32d that has received the first data determines whether or not an alarm request is included in the first data (s32). Then, if an alarm request is included in the first data, the power supply control unit 38 is requested to supply power (s33). Further, the alarm request included in the first data and the identification information for specifying the transmission source are stored in the data memory 32c. On the other hand, when the alarm request is not included in the first data, the first data including the alarm request is always on standby. Further, the first control unit 32d identifies the alarm request and the transmission source to the first communication unit 33 toward the alarm command devices 4a and 4c and the second alarm output device 5 that are not the transmission source. Second data including information is transmitted (s35). The power supply control unit 38 that has received a request for power supply causes the light emitter 6a to supply high voltage power from the battery 7a. As a result, the light emitter 6a is activated and lit (s34).

  Moreover, in the alarm command devices 4a to 4c, as shown in FIG. 8, the second data is received as a response to the transmission of the first data to the first alarm output device 3 as a server (s46). . Then, each second control unit 42d of each of the alarm command devices 4a to 4c determines whether the second data includes the identification information of the alarm request and the source of the alarm command (s47). When the second data includes the identification information of the source of the alarm request and the alarm command, the second control unit 42d of each alarm command device (4a, 4c in the present embodiment) is either In order to notify the surroundings that an alarm command has been issued by another alarm command device 4 (4b in the present embodiment), a buzzer sound is generated from the buzzer 45c and the display lamp 45b is turned on as an alarm. (S48). Further, the identification ID of the alarm command device as the transmission source is displayed on the display unit 44.

  In the second alarm output device 5, as shown in FIG. 9, the third data is transmitted to the server of the first alarm output device 3 (s51), and the fourth data is returned as the response. (S52). Here, the transmission of the third data is a communication for requesting the fourth data including the alarm request updated from the server and the identification information of the source of the alarm command at a predetermined timing. When transmitting the third data, the third control unit 52d waits for reception of the fourth data as a response from the server at a predetermined timing after the transmission. The reception of the fourth data from the server in response to the transmission of the third data at regular intervals is also used for network disconnection confirmation.

  Then, the third control unit 52d determines whether the fourth data includes the identification information of the source of the alarm request and the alarm command (s53). If the fourth data includes the identification information of the alarm request and the source of the alarm command, the third control unit 52d requests the power supply control unit 58 to supply power (s54). In addition, when the fourth data includes the identification information of the source of the alarm request and the alarm command, the third control unit 52d causes the display unit 54 to display the identification ID of the source alarm command device. Also good. On the other hand, when an alarm request is not included in the fourth data (No in s53), the fourth data including the alarm request is always on standby (s51). The power supply control unit 58 that has received the request for power supply supplies the high-voltage power from the battery 7a to the light emitter 16a, so that the light emitter 16a is activated and lights up (s55).

  As explained above, by turning on the light emitters 6a and 16a in an emergency, when an unexpected situation occurs in the construction site and the train tries to enter the construction site, it is operated that the train should stop. Can inform the hand. In this embodiment, an example in which a light emitter is used as an alarm device has been described. However, a siren device is used instead of the light emitter, or the light emitter and the siren device are used in combination. May be.

  It is preferable that the light emitters 6a and 16a lit by a command from the alarm command device 4b can be released by pressing the release push button 41b for releasing the command by the emergency push button 41a of the alarm command device 4b.

  In the train stop system 100, a local area network (LAN) is constructed in the construction site. Specifically, as shown in FIG. 1, access points 2 a to 2 e for wireless connection are installed on a wired network trunk line 1 extending in the construction site C. In addition, in the train stop system 100 shown in FIG. 1, the example which has arranged the access point of the number corresponding to each of the 1st warning output device 3, the 2nd warning output device 5, and the warning instruction devices 4a-4c is shown. However, the present invention is not limited to this example, and the number of access points can be appropriately increased or decreased according to the radio wave conditions.

  In the train stop system 100 described above, a communication network using the wired network trunk line 1 is shown, but a plurality of short-range wireless communication access points are relayed to each other by a roaming function instead of the wired network trunk line 1. Thus, the constructed wireless network trunk line 11 may be used. A train stop system 200 having such a configuration will be described with reference to FIG.

  FIG. 10 is a schematic explanatory diagram illustrating an overall configuration of a train stop system 200 according to another embodiment. In FIG. 10, 12a to 12e are short-range wireless communication access points, and 13a to 13e are short-range wireless communication access points. Elements having the same reference numerals as those shown in FIG. 1 indicate the same elements.

  The short-range wireless communication access points 12a to 12e shown in FIG. 10 have a short-range range of about 50 m to 3 km, for example, with the antennas 13 a to 13 e as a radio wave range. Then, the radio network trunk line 11 is constructed without laying a wired cable such as a LAN cable or an optical cable by overlapping the radio wave ranges of the short-range wireless communication access points 12a to 12e and relaying them by the roaming function. ing. According to the train stop system 200 using a wireless network trunk constructed only by such short-range wireless communication access points, a plurality of short-range wireless communications are taken at predetermined intervals without laying wired cables. Access points 12a-12e are established, and communication is established with each of the short-range wireless communication access points 12a-12e, the first alarm output device 3, the alarm command devices 4a-4c, and the second alarm output device 5. The train stop system 200 can be installed only by making it.

  Furthermore, in the train stop system 100 and the train stop system 200 described above, an example using a wireless access point has been described. However, a wired cable such as a LAN cable or an optical cable may be used to connect to the network trunk line. As an example of such a configuration, a train stop system 300 constructed by connecting each device to a network trunk line using a LAN cable will be described with reference to FIG.

  FIG. 11 is a schematic explanatory diagram showing the overall configuration of the train stop system 300. In FIG. 11, 22 is a wired network trunk, and 22a to 22e are switching hubs that relay LAN cables. Elements having the same reference numerals as those shown in FIG. 1 indicate the same elements.

  The first alarm output device 3, the alarm command devices 4a to 4c, and the second alarm output device 5 shown in FIG. 11 are connected to the switching hubs 22a to 22e and connected to the network trunk line 22 by wire. In a mountainous area or a construction site where there is a lot of radio wave interference, a train stop system in which the stability of communication is ensured can be installed by using a LAN constructed only by wire.

  Although the train stop system according to the present invention has been described above, the train stop system according to the present invention can be used in various modified forms as long as the effects of the present invention are not impaired in addition to the forms described above. it can. For example, in each form mentioned above, you may use the form which uses a radio | wireless area | region and a wired area | region in combination as LAN constructed | assembled.

1,11,21 Network trunk line 2a to 2e Access point 3 First alarm output device 4 (4a to 4c) Alarm command device 5 Second alarm output device
6a, 16a Light emitter 7a, 7b Battery (power supply device)
7c Solar panel 12a-12e Short-range wireless access point 13a-13e Antenna 22 LAN cable 22a-22e Switching hub 32 First microcomputer 32a, 42a, 52a Program memory 32b, 42b, 52b CPU
32c, 42c, 52c Data memory 32d First control unit 33 First communication unit 34, 44, 54 Display unit 38, 58 Power supply control unit 41 Input unit 41a Emergency push button 41b Release push button 42 Second microcomputer 42d Second 2 control unit 43 second communication unit 45a speaker 45b display lamp 45c buzzer 46 ID setting unit 47 output power control unit 52 third microcomputer 52d third control unit 53 third communication unit 100, 200, 300 Train stop system

Claims (9)

A train stop system installed at a construction site along a railway track,
LAN (Local Area Network) built in the construction site,
A first alarm output device arranged in order from the beginning of the construction site along the railroad track, and at least one alarm command device arranged at intervals from each other,
Connected to the LAN, the first alarm output device is a server, the alarm command device is a client,
The first alarm output device includes a first alarm device, a first control unit, and a first communication unit,
The warning command device includes an input unit that receives a warning command from a construction worker, a second control unit that generates a warning request when the warning command is input, and a second communication unit,
The first communication unit receives the alarm request from the second communication unit and outputs the alarm request to the first control unit, and the first control unit is configured to output the first alarm device based on the alarm request. Train stop system for construction, characterized by operating A plurality of the alarm command devices having different identification information from each other,
2. The construction train stop according to claim 1, wherein the server specifies the identification information of the warning command device that is a transmission source of the warning command, and provides the identification information to another warning command device other than the transmission source. system.   3. The construction train stop according to claim 2, wherein the other warning command device further includes a display unit for displaying the warning command device of the transmission source when the identification information is given from the server. system.   The construction train stop system according to claim 3, wherein the warning command device further includes a notification unit that issues a warning when the identification information is given from the server. A second alarm output device serving as a client, which is disposed at the end of the construction site and includes a second alarm device, a third control unit, and a third communication unit;
The third communication unit is supplied with the alarm request from the first communication unit and outputs the alarm request to the third control unit, and the third control unit is configured to output the second alarm device based on the alarm request. The train stop system for construction according to any one of claims 1 to 4, wherein the system is operated.   The construction train stop system according to any one of claims 1 to 5, wherein the alarm command device further includes a notification unit that issues a disconnection alarm when communication is interrupted for a predetermined time or more.   The construction LAN stop system according to any one of claims 1 to 6, wherein the LAN includes at least one access point for performing wireless communication.   8. The construction train stop system according to claim 1, wherein the first alarm output device includes, as a power source, a battery connected to a solar panel that generates power by sunlight.   The construction train stop system according to any one of claims 1 to 8, wherein the first alarm device includes at least one selected from a light emitter and a siren device.

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