This disclosure relates to railway traffic control, and more specifically, a system, apparatus, and method for railway traffic control to address concerns for safety of railway workers working on or near railroad tracks.
Railway transportation is run under strict operational guidelines or roles, in order to operate safely. Most of these guidelines are standard amongst commercial railway traffic. Examples of transport standards include interlock signals, centralized traffic control (CTC), rule 251, etc.
Interlocking signals govern movement within a sector controlled by an interlock. For example, on a specific track line, a track may be divided into sections of 400 to 2500 m, on each of which trains move at a speed depending on an interlocking signal exhibited by an interlock at an entrance to the section. That is, the interlocking signal displays a color system which instructs the conductor of the train, or the train operating by automated response, how to move through the upcoming section of track. Interlocking systems usually incorporate a 3-color system by which the train, or train conductor, is informed to proceed at regular speed, is informed to proceed at a reduced speed or is prohibited from proceeding through the upcoming section.
While interlocking systems can be operated manually, currently most interlocking systems are controlled electronically. One method of controlling all of the interlocks within a rail system is through a centralized traffic control (CTC), or traffic control system (TCS). A CTC is used for monitoring, tracking and operating trains traversing tracks throughout a network. The CTC is controlled by a single person known as a train dispatcher.
In order for the train dispatcher to make appropriate train control decisions regarding how the train should be operated, various information and data must be obtained and presented. Information regarding track conditions, train traffic, scheduling, etc., are presented on a control console which may include a map of the entire rail system controlled by the CTC. Through the control console, the dispatcher has control of each interlock signal (that is, the dispatcher controls the train traffic and flow of train traffic using the interlocks) and is constantly made aware of the positions of trains in the railway system as such positions are electronically reported by signals present throughout the railway system. In addition, in order to provide for safe traffic control and avoid accidents or collisions, signals are provided throughout the track network, or interlocks.
The interlocks may be controlled from the CTC in any of various different ways, including, e.g., direct wiring, by pulse codes sent over a wire to distant locations, etc. In addition, interlocks can also be controlled by a native mechanism detecting presence of a train on the track. That is, when a train occupies a certain section of track, the interlock prevents other trains from proceeding onto the same
Further, there are additional safety systems on the train itself, such as automatic train control (ATC). A common feature of many of such automated train control systems is the need for constant or nearly constant communications between onboard train control systems and an offboard hub radio connected to control equipment located along the wayside or in a central office. In some systems, the offboard control equipment generates movement authorities which authorize the train to move in one or more sections of track. In some systems, the offboard equipment informs the onboard train control system of the presence of other trains in the vicinity. In yet other systems, the offboard equipment provides information such as temporary speed restrictions and work zone information to the onboard train control system. Such systems protect against a number of human errors on the part of the train drivers, one of the basics of the system being that the train is provided with a computer which receives traffic information, such as stop signals and speed limits, from a plurality of transmitters along the track. Thus, the computer may bring the train to a standstill regardless of what the train driver does when the train arrives at a stop signal.
Even with all these safety features present in a railway system, railway accidents occur, with many being fatal. For example, one study reported that there were 39 roadway worker accidents that occurred between January 1997 and the end of 2011, in which 41 roadway workers perished while attending to tasks such as inspection, construction, maintenance, or repair of railroad track, bridges, roadway, signal and communication systems, electric traction systems, roadway facilities or roadway maintenance machinery on or near track, operating as flagmen or watchmen/lookouts for other roadway workers, etc.
There remains a need for further safety measures to protect the lives of railway workers.
This disclosure provides tools (in the form of systems, apparatuses, methodologies, etc.) for enhancing railway traffic control, as supplemental measures directed to safety of railway workers.
For example, a centralized railway control system may be adapted (such as via computer hardware, software, or a combination) to include providing on a user terminal a user interface including a block placing part to place a block on one or more specified track sections to permit a railway field worker to enter the track sections while blocking railway traffic to said track sections, generating a removal code and transmitting the removal code to the electronic contact address of the railway field worker, and permitting the block to the track sections to be removed only upon entry of the removal code in the centralized railway control system. Such process may be largely automated via programming such that upon placement, by the block placing part, of the block of railway traffic to the specified track sections, the removal code is automatically transmitted, by a code generation part, to the electronic contact address of the railway field worker, and the block of railway traffic to the specified track sections remains in place in the centralized railway control system until the entry of the removal code in the centralized railway control system to cause a block removal part to remove the block on said one or more track sections.
In another aspect, the adaptation may include a RTC user interface to permit a user (e.g., railway traffic controller (RTC) or train dispatcher) to specify a track section(s) to be blocked, specify an instruction to the centralized railway control system to block the railway traffic to the specified track section(s), and specify identifying information of the railway field worker performing (or to be performing) work in the specified track section(s).
In another aspect, the adaptation includes a block removal user interface to permit a user to enter the removal code to cause the block removal part to remove the block on said one or more track sections. Such block removal user interface may be provided in any of various ways. For example, the block removal user interface may be provided within a mobile application or web page through which the railway field worker can enter the removal code manually or orally (i.e. including a voice or speech interface part). As another example, the removal code may be embedded in a link in a message transmitted by email or messaging to the electronic contact address of the railway field worker, and the railway field worker can simply cause the removal code to be entered by activating the link in the message received by the railway field worker. In another example, the block removal user interface may be provided on the same user terminal on which the block placing part is disposed. Further, a voice or speech interface part may be disposed on the system-side to process a voice message (such as received via a telephone call from terminal 103 of the railway field worker), extract the removal code from the voice message, and enter the block removal code. In each instance, the block of railway traffic to the specified track sections remains in place in the centralized railway control system until the entry of the removal code through the block removal user interface. Further, entry of the removal code may also require entry of identification of the user entering the removal code, and removal of the block may also require not only the removal code but also confirmation that the user entering the removal code is authorized to remove the block. The block removal user interface may further require, in addition to entry of the removal code, the user to specify that confirmation that the track sections have been cleared has been obtained from the railway field worker associated with the block, before the block removal user interface permits the removal code to be transmitted to the block removal part.
In another aspect, the system may include a railway control database registering block identifying information, including block limits identifying the one or more blocked track sections, along with the removal code for removing the block of the track sections. Further, the railway control database may register additional information, such as identification of the user who specified the instruction to block the track sections, notes specifying reasons for the block, date and time at which the block was placed, etc. The railway control database may further register block removal information identifying date and time at which the block was removed and identifying the user who entered the removal code and who specified that confirmation that the track sections have been cleared was obtained from the railway field worker associated with the block.
The aforementioned and other aspects, features and advantages can be more readily understood from the following detailed description with reference to the accompanying drawings wherein:
This patent specification describes tools (in the form of methods, apparatuses and systems) that controls train traffic within a railway system using, but not limited to, standardized rules or timetables described in the Background section of this specification.
In describing exemplary embodiments illustrated in the drawings, specific terminology is employed for the sake of clarity. However, the subject matter of this patent specification is not intended to be limited to the specific terminology so selected and it is to be understood that each specific element includes all technical equivalents that operate in a similar manner.
The drawings show examples of implementations of the subject matter of this patent disclosure in several computing environments. However, it should be understood that the subject matter of this disclosure can be utilized by any computing device including but not limited to PDAs (personal digital assistants), cell phones, personal, notebook and workstation computers, kiosks, other information terminals, WIC (or another) pager, etc. In addition, the subject matter of this disclosure might be provided as services in a modular fashion by other devices connected by a communication network.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views, there is described tools (systems, apparatuses, methodologies, computer program products, etc.) that can be integrated in a railway traffic control system.
The network 102 can be any data network, a local area network, a wide area network or any type of network such as an intranet, an extranet (for example, to provide controlled access to external users, for example through the Internet), a private or public cloud network, the Internet, etc., or a combination thereof. Further, other communications links (such as a virtual private network, a wireless link, etc.) may be used as well for the network 102. In addition, the network 102 preferably uses TCP/IP (Transmission Control Protocol/Internet Protocol), but other protocols such as SNMP (Simple Network Management Protocol) and HTTP (Hypertext Transfer Protocol) can also be used. How devices can connect to and communicate over networks is well-known in the art and is discussed for example, in “How Networks Work”, by Frank J. Derfler, Jr. and Les Freed (Que Corporation 2000) and “How Computers Work”, by Ron White, (Que Corporation 1999), the entire contents of each of which are incorporated herein by reference.
The rail personnel 104 is a database that can be either connected to or inside the railway traffic control terminalapparatus 105. The rail personnel contact data 104 stores information regarding the maintenance workers used for traveling, inspecting and working on blocked rails. For example, the information stored can include the name of the maintenance worker, primary contact, secondary contact, previous assignment, current assignment, etc., as shown via user interface display in
The railway traffic blocking apparatus is programmed to control the traffic of an entire railway network. The block placer 101A is configured to stop traffic within a certain length of rail line. That is, once a block is placed, no train can traverse the blocked section of rail. For example, in the case of a railway controlled by multiple interlocks, the block placer 101A causes those interlocks to output a STOP signal, therefore, stopping any train traffic within the rails controlled by that interlock. By doing this, maintenance workers and railway personnel can travel, inspect and work on the rails without the danger of oncoming train traffic. Trains that are scheduled to traverse said blocked tracks either come to a complete stop, electronically or mechanically, before passing the interlock or are rerouted using tracks that are not in a blocked state. However, this disclosure is not limited to a railway traffic control system implementing interlocks. This system can be implemented on any configuration in which there is control of the traffic of a railway system.
The code generator 101B is configured to produce a removal or release code, such as a cipher which is random, pseudo-random, secret, etc., and stored on the terminalcomputer. A new random cipher may be generated for each instance of traffic blocking. This removal or release code is then sent to another terminalterminals belonging to the railway personnel who are scheduled to travel, inspect or work on the specific rails being blocked.
The block remover 101C is programmed to remove the previous block, or plurality of blocks set by the block placer 101A. The block remover 101C is dependent on the code produced by the code generator 101B. As described in detail below, a block cannot be removed without the input of the removal or release code.
The user interface 101D is configured preferably for the ease of use for the railway traffic controller (RTC). As shown by way of examples in
The user interface 101D may be a mobile application, a web page or some other software component, on a terminalcomputer (such as a mobile device). Such terminaldevice preferably is configured to communicate through a computer or data network to obtain content and data from an external source. However, it should be appreciated that the inventive aspects described herein can be employed even if the mobile device is not configured to connect to a data network, and/or is not connected to a data network.
An example of a configuration of a user terminal (e.g., the terminal 103) or computer is shown schematically in
The storage 203 can provide storage for program and data, and may include a combination of assorted conventional storage devices such as buffers, registers and memories [for example, read-only memory (ROM), programmable ROM (PROM), erasable PROM (EPROM), electrically erasable PROM (EEPROM), static random access memory (SRAM), dynamic random access memory (DRAM), non-volatile random access memory (NOVRAM), etc.].
The network interface 206 provides a connection (for example, by way of an Ethernet connection or other network connection which supports any desired network protocol such as, but not limited to TCP/IP, IPX (Internetwork Packet Exchange), IPX/SPX (Internetwork Packet Exchange/Sequenced Packet Exchange), or NetBEUI (NetBIOS Extended User Interface)) to a network (e.g., network 102) to enable the terminal device to communicate with another device through the network.
Each of the terminal 103, rail personnel database 104 and railway traffic control apparatus 105 can be configured to communicate with each other through the network 102. The railway traffic control terminalapparatus 105 can be configured to request data from the rail personnel contact data 104 through the network 102, as shown in
The release code is then sent to the terminal 102103. This terminal 102103 is the contact associated with the designated worker, and the electronic address of this terminal is found within the personnel data received from the rail personnel contact data 104. By this system, only the railway traffic control apparatus 105 and terminal 102103 receive the release code generated by the railway traffic control apparatus 105.
Additionally,
As shown in the example illustrated in
Once the block is put into place, the corresponding section on the railway network 500 displays the section of track being blocked. In addition, the railway traffic control terminalapparatus 105 generates a release code, stores the release code, and sends the code to the maintenance worker designated for track work, i.e. maintenance worker 12. As shown in
The blocks are then tabulated by the railway traffic control apparatus 105 as depicted in
Additional information can be accessed though this table by highlighting a cell of the table and selecting info, as shown in
Without the input of the release code, the remove option is not available to be selected. In a different embodiment, the release code may be obtained from the storage of the railway traffic control terminalapparatus 105.
In the case where there are multiple maintenance workers assigned to a certain track section, there may be provided one release code to one, multiple or all of the maintenance workers assigned. That is, The train traffic controller may input that the release code be specified to one maintenance worker, preferably a supervisor or foreman, to multiple maintenance workers or to all of the maintenance workers assigned to work on a given track section. Also, in another embodiment, in a case where there are multiple workers assigned for a certain track section, there may be provided multiple unique release codes which would then all be required to be input into the train traffic control terminalapparatus 105 by the train traffic controller in order to be able to remove blocks on certain track sections.
In another embodiment, the train traffic controller may be asked to verify that a railway section is cleared before receiving the option to remove a train block. As shown in
In another embodiment, once the rail traffic controller unblocks a section of track, the railway traffic control terminalapparatus 105 may send a message to the worker, or plurality of workers, associated with working on the previously blocked track in order to inform them that the track has been unblocked and is no longer a safe environment to work in.
Next, the method of placing a block on a track section will be described with reference to
After a request to block a certain section of track is sent, the railway traffic control terminalapparatus 105 checks if there is one or more of the sections currently has a block placed, as shown in S1204. If one or more of the designated sections does not have a block placed, then the railway traffic control terminalapparatus 105 opens a user interface for the railway traffic controller to designate a type of block to set and a maintenance worker for the blocked section in S1206. If the railway traffic control terminal sees that a block is already in effect (S1205), then the railway traffic control terminalapparatus 105 allows the railway traffic controller to change the existing block type and maintenance worker using the same interface. The interface is then opened in S1206.
The railway traffic controller then inputs the type of block and assigns a worker to work on the blocked section. The railway traffic controller also has the option to block the track for purposes of an emergency and not necessarily for maintenance work in S1207. Once the railway traffic controller assigns a block type and/or a corresponding maintenance worker, the railway traffic control terminalapparatus 105 checks the status of the selected block in S1208. If the current selected section has an existing block, the railway traffic control terminalapparatus 105 waits for a response from the interlocks of the corresponding section to send an indication that a new block can be established in S1209. Once this indication is received in S1210, the railway traffic control terminalapparatus 105 enables the place button of the user interface (S1211). If the selected section has no previous active block, the railway traffic control terminalapparatus 105 immediately enables the place button on the user interface.
Once the place button is selected, the railway traffic control terminalapparatus 105 generates a place time and enables safety measures so that the block cannot be removed without the input of the secret code generated (S1212). Finally, the railway traffic control terminalapparatus 105 sends the secret removal code to the corresponding one or more maintenance workers (S1213) if the railway traffic controller has selected maintenance workers for the given block.
Once the secret code is received, the secret code may be input to the designated field in S1308. The railway traffic control terminalapparatus 105 checks the secret code with the code saved in its memory in S1309. If the code is incorrect, (S1309, NO), the railway traffic control terminalapparatus 105 will prompt the user to input the code again (S1308). If the code is correct (S1309, YES), the railway traffic control terminalapparatus 105 will prompt the user to enter information into any remaining fields in S1310. In S1311, the railway traffic control terminalapparatus 105 checks that all information input into all fields is correct and that all fields are filled in. After this check is performed by the railway traffic control terminalapparatus 105, the remove button is enabled on the form (S1312) and the railway traffic controller may remove the block on the corresponding track section.
The aforementioned specific embodiments are illustrative, and many variations can be introduced on these embodiments without departing from the spirit of the disclosure or from the scope of the appended claims. For example, elements and/or features of different examples and illustrative embodiments may be combined with each other and/or substituted for each other within the scope of this disclosure and appended claims.
The orders in which the steps are performed in the aforementioned methods are not limited to those shown in the examples of
Further, conventional systems can be modified to include the aspects described herein. As an example, a means may be added to a conventional interlock system by which the railway worker has partial control of the interlock system at the times that maintenance work is needed on a certain train block. In such modification, a system, apparatus and/or method may be provided to control the interlocks in a railway system as an interface between the railway workers and the interlock control. Thus, in a case in which maintenance is to be performed on a certain rail block, which is controlled by an interlock, the interlock can be configured to send out a stop signal for all incoming trains, to block train traffic to such portion of the rail system. In addition, once the interlock is placed in a “stop traffic” state, a release code is transmitted to an electronic contact address corresponding to the railway worker.
Once a block has been placed, the interlock remains in a blocked state, until the maintenance worker supplies the release code, which was received at the time the interlock started, and the release code is entered in the interlock control system. So long as the block is in place, the maintenance worker can perform on-track work, without interference of oncoming train traffic. After the maintenance worker finishes the assigned work and is clear of the train tracks, he/she may then supply the interlock control system with the release code, and the interlock control system in turn can release the interlock over the block.
Accordingly, the railway worker has more control over the traffic through the rail block in which the worker is working, and fatal on-track accidents can be reduced.
Additional variations may be apparent to one of ordinary skill in the art from reading U.S. Provisional Application No. 61/893,547, filed Oct. 21, 2013 and entitled “SYSTEM, APPARATUS AND METHOD FOR RAILWAY TRAFFIC CONTROL”, the entire contents of which are incorporated herein by reference.
This application claims the benefit of U.S. Provisional Application No. 61/893,547, filed Oct. 21, 2013 and entitled “SYSTEM, APPARATUS AND METHOD FOR RAILWAY TRAFFIC CONTROL”.
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Number | Date | Country | |
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Child | 15928955 | US |