This invention relates to warning systems for what are known in the U.S. as railroad grade crossings (sometimes referred to in the U.K. as level crossings), which are locations at which railroad tracks intersect roads. The warning systems typically include lights, bells and a gate arm that blocks the road when a train is approaching the crossing.
The lights, bells and gate arms of the warning system are typically controlled by a controller that includes an input from a grade crossing predictor circuit. Grade crossing predictor circuits are able to determine a distance from the train to the crossing and can determine whether the train is approaching the crossing or moving away from the crossing. This ability allows the controller to activate the warning system with a constant warning time prior to the train reaching the crossing. These circuits typically employ tuned shunts at either end of an approach area to a crossing and work by transmitting a signal (typically a low frequency signal in the audio range) through the rails and shunts and sensing an inductance (or impedance) of the circuit formed by the track rails and shunts. When a train approaches a crossing, the train's axles and wheels create a short circuit between the rails, which lowers the total apparent inductance. By monitoring the inductance or impedance changes, the distance and speed of the train can be determined so that the warning system can be activated with a constant warning time.
Unfortunately, grade crossing predictor circuits do not work in all circumstances. For example, grade crossing predictor circuits may not work, or may not work reliably, in electrified territory (i.e., territory in which propulsion current is supplied through a third rail or a catenary wire system) and other areas with significant electromagnetic interference. In such circumstances, it is necessary to provide an alternative technique for controlling a warning system for a grade crossing.
One possible alternative technique is to control the grade crossing using a signal from a track occupancy circuit. A track occupancy circuit is a type of circuit that detects the presence or absence of a train in a section of track. A grade warning system controller can be configured such that the warning system activates when the track occupancy circuit indicates that a train is present in a section of track prior (with respect to a direction in which the train in traveling) to the grade crossing. In systems such as these, the length of the section of track monitored by the track occupancy circuit is chosen such that detection of a train traveling at the fastest authorized train speed in the block of track monitored by the track circuit will result in activation of the warning system at a desired amount of time prior to arrival of the train at the crossing.
Systems such as these suffer from a significant drawback: since the warning system activates as soon as a train is detected in the section of track monitored by the block occupancy circuit, a train traveling at a speed significantly lower than a maximum authorized speed will result in activation of the warning system a significantly longer period of time prior to arrival of the train at the crossing than is necessary or desired.
In the following detailed description, a plurality of specific details, such as types of encoding schemes and types of track occupancy circuits, are set forth in order to provide a thorough understanding of the preferred embodiments discussed below. The details discussed in connection with the preferred embodiments should not be understood to limit the present inventions. Furthermore, for ease of understanding, certain method steps are delineated as separate steps; however, these steps should not be construed as necessarily distinct nor order dependent in their performance.
One way in which the problem discussed above may be solved is to utilize an indication of the presence of a train from a track occupancy circuit together with an indication of the speed of the train to control a grade crossing warning system. The speed and presence of the train may be determined using a sensor that directly detects the train and measures the speed of the train, such as a radar or laser system similar to those used by police departments. The speed of the train may be used to select or calculate a desired delay, after which a grade crossing warning system will be activated. The use of such sensor devices has some drawbacks, not the least of which is the necessity of installing and maintaining additional equipment.
Another solution discussed in detail herein is to use another signal that indirectly indicates a speed of the train together with the indication of train presence from the track occupancy circuit in order to control the grade crossing warning system. An example of a signal that indirectly indicates a speed of the train is a signal aspect associated with the block of track. The signal aspect indicates the maximum allowable speed of the train. By assuming the train is traveling at the maximum allowable speed indicated by the signal aspect (which can change frequently over time), rather than the maximum allowable speed for the section of track (which is typically permanent, although sometimes changes temporarily), the amount of time wasted by a premature triggering of the grade crossing warning system can be significantly reduced or even eliminated.
An embodiment of such a system 100 is illustrated in
As is known in the art, the lamps may be controlled automatically by track occupancy circuits (e.g., an ABS, or automatic block signaling, system) which again may be the same or different from those track occupancy circuits used for control of the grade crossing warning system, by a central office (e.g., a centralized track control, or CTC, system), or by other means. In addition to lighted wayside signal devices, wayside signaling device 110 can also include devices and systems that provide signal aspect information to a train electronically/electrically such as by radio or through the rails (e.g., cab signal systems).
In addition to wayside signal device 110, the system 100 also includes a track occupancy circuit 120. The track occupancy circuit 120 may be any type of track occupancy circuit, and is preferably an AC track occupancy circuit. The track occupancy circuit 120 outputs a signal that indicates whether or not a train is present in a block of track associated with the track occupancy circuit. The system 100 also includes an island circuit 130, which is a track occupancy circuit that detects the presence of a train in the area of track that intersects the road (referred to in the art as the “island”). A signal aspect from the wayside signal device 110, a signal indicative of the presence of a train in the track block from the track occupancy circuit 120, and a signal from the island circuit 130 are fed to a control unit 140. The wayside signal device 110, the track occupancy circuit 120 and the island circuit 130 may be connected to the control unit 140 by line wire, by buried cable, by a radio link, or by any other suitable means. The control unit 140 may be realized using a microprocessor, a digital signal processor, a microcontroller, discrete logic, a combination thereof, or any other suitable technology. The control unit 140 uses the inputs from the wayside signaling device 110, the track occupancy circuit 120 and the island circuit 130 to control a grade crossing warning system 150. As discussed above, the grade crossing warning system 150 can include lights, bells, and/or a crossing gate (not shown in
Operation of the control unit 140 will be discussed with reference to the flowchart 200 of
If a train is detected at step 206, the delay period is determined at step 208 based on the maximum allowable speed determined at step 204. The delay period is the amount of time after the detection of a train that the control unit will wait before activating the grade crossing warning system 150. The delay period will depend upon the maximum allowable speed of the train and the distance from the start of the block of track monitored by the track occupancy circuit 120 to the road (this distance is sometimes referred to as the approach length). The approach length is typically chosen such that no delay is necessary for a train traveling at the maximum authorized speed, so that the grade crossing warning system 150 is activated immediately upon detection of a train by the track occupancy circuit 120 when the signal aspect is at its most permissive. For slower traveling trains (as indicated by signal aspect), a delay between the detection of the train by the track occupancy circuit and the activation of the warning system 150 is needed to avoid having the warning system 150 activated (and the road blocked) for longer than necessary. Those of skill in the art will recognize that this step 208 may also be performed by a table lookup using the maximum speed as an index. Those of skill in the art will further recognize that step 208 may be combined with step 204 in some embodiments by using the signal aspect as an index into a table of delay periods, which can be calculated in advance because the approach length and the maximum speeds associated with each signal aspect are predetermined.
After the delay has been determined at step 208, the control unit 140 starts an internal delay timer and determines when the delay timer times out at step 210. If the delay timer times out at step 210, the control unit 140 activates the warning system 150 at step 212. The control unit 140 then waits until the train is detected by the island circuit 130 at step 214, which signifies that the train has reached the road. Next, the control unit 140 waits until the island circuit indicates that the train is no longer detected by the island circuit 130 at step 216, which indicates that the train has moved past the road. The control unit 140 then deactivates the warning system 150 and the process is repeated.
In the embodiment of
In a typical installation, a track occupancy circuit will be placed on either side of the road as shown in the system 300 of
In the system 300, the track occupancy circuit transmitters 120a, 122a are configured to transmit a code based on an input from a external device as disclosed in commonly owned co-pending U.S. application Ser. No. 61/226,416 entitled “Track Circuit Communications,” preferably using a frequency shift key technique as disclosed in commonly owned co-pending U.S. application Ser. No. 12/724,800 entitled “Decoding Algorithm for Frequency Shift Key Communications” (the “FSK application”). The contents of both of these applications are hereby incorporated by reference herein. The particular code is chosen based on an input from a respective wayside signal device 110, 112 such that a different code is chosen depending on the signal aspect. The track occupancy circuit receivers 1206, 122b are configured to decode the code transmitted by the respective transmitters 120a, 122a. The receivers are preferably configured to perform the decoding algorithm disclosed in the aforementioned FSK application. The control unit 140 utilizes the decoded code to control the warning system 150. The actual delays corresponding to the decoded codes may be set by a user using the I/O unit 170 during set up of the system 300. The embodiment of
The processing performed by the control unit 140 of the system 300 of
When the track occupancy circuit 120 detects an incoming eastbound train at step 406, the control unit 140 sets an internal timer to the corresponding delay determined at step 404 waits until the time expires at step 408. When the timer expires at step 408, the warning system 150 is activated at step 410. The control unit 140 then waits until the train is detected in the island circuit 130 at step 412. When the train clears the island circuit at step 414, the control unit 140 then checks to ensure that the train is detected by the track occupancy circuit 122 on the east side of the road 320 at step 414. If so, the warning system 150 is deactivated at step 416 and the process repeats.
Those of skill in the art will recognize that devices other than a signal aspect may be used to determine indirectly a maximum speed of a train. For example, in some situations, a trailing point switch (not shown in the figures) may be connected upstream of the track occupancy circuit 120 to switch either a high speed track or a low speed track to the track 310. In such a situation, the position of the switch may be used to determine the maximum allowable speed depending on which track is switched onto the track 310. Those of skill in the art will recognize that there are several other devices which may similarly indicate a time varying maximum allowable speed applicable to an inbound train.
The foregoing examples are provided merely for the purpose of explanation and are in no way to be construed as limiting. While reference to various embodiments is made, the words used herein are words of description and illustration, rather than words of limitation. Further, although reference to particular means, materials, and embodiments are shown, there is no limitation to the particulars disclosed herein. Rather, the embodiments extend to all functionally equivalent structures, methods, and uses, such as are within the scope of the appended claims.
The purpose of the Abstract is to enable the patent office and the public generally, and especially the scientists, engineers and practitioners in the art who are not familiar with patent or legal terms or phraseology, to determine quickly from a cursory inspection the nature and essence of the technical disclosure of the application. The Abstract is not intended to be limiting as to the scope of the present inventions in any way.