A broken wheel detection system for detecting broken wheels on rail vehicles even when such vehicles are moving at a high rate of speed.

A housing, an LED system, and an alignment module supported in the housing to mount the LED system in an interior space in the housing, dampen vibration(s) of the LED system in the interior space, and automatically align a focal point of the LED system. Such a lightening system may be applicable for a traffic/rail signal.

A housing, an LED system, and an alignment module supported in the housing to mount the LED system in an interior space in the housing, dampen vibration(s) of the LED system in the interior space, and automatically align a focal point of the LED system. Such a lightening system may be applicable for a traffic/rail signal.

This invention relates generally to a device which utilizes a solar powered Internet of Things (IoT) technology to remotely monitor the position of railroad switches and derails and send updates by cellular signal to a database via a cloud platform. This new and novel technology allows for cost effective remote monitoring of railroad switch points and derails in dark territory without the need for wayside power or radio communication equipment. The device is also capable of being integrated with dispatch CAD (computer automated dispatch), wayside signalization, positive train control devices, automatic alert generations, active warning devices, crossing gates, as well as power assisted railroad switches.

This invention relates generally to a device which utilizes a solar powered Internet of Things (IoT) technology to remotely monitor the position of railroad switches and derails and send updates by cellular signal to a database via a cloud platform. This new and novel technology allows for cost effective remote monitoring of railroad switch points and derails in dark territory without the need for wayside power or radio communication equipment. The device is also capable of being integrated with dispatch CAD (computer automated dispatch), wayside signalization, positive train control devices, automatic alert generations, active warning devices, crossing gates, as well as power assisted railroad switches.

A system and method is proposed to ensure detection of signal light integrity and viewability. The system includes a wireless network of signal light monitors attached unobtrusively to the sun visors on each signal light for which monitoring is required. Each signal light monitor includes diverse sensors which detect signal light integrity and viewability. The detection sensors are simultaneously active to detect signal light intensity, color intensity and viewability. The information obtained from the sensors is transmitted wirelessly to a base signal light monitor. The base signal light monitor communicates this information over a mesh network to an edge processor. The network is self-healing and ensures data integrity using a pre-calculated communication link if a communication link between base signal light monitors is lost or broken. The edge processor is capable of image and condition analysis on the detection data and communicates events to an enterprise network for action.

An optical system (100) for a light emitting diode (LED) signal includes a plurality of light emitting diodes (LEDs) (12, 14), a plurality of optical lenses (20, 40, 60, 80) for diverging and collimating light generated by the plurality of LEDs (12, 14), wherein the plurality of LEDs (12, 14) and the plurality of optical lenses (20, 40, 60, 80) are sequentially arranged in an axial direction, and wherein the plurality of optical lenses (20, 40, 60, 80) are configured such that by altering an axial position of one of the optical lenses (20, 40, 60, 80) from a first defined axial position to a second defined axial position, a final angular light distribution of the optical system (100) is variable.

An optical system (100) for a light emitting diode (LED) signal includes a plurality of light emitting diodes (LEDs) (12, 14), a plurality of optical lenses (20, 40, 60, 80) for diverging and collimating light generated by the plurality of LEDs (12, 14), wherein the plurality of LEDs (12, 14) and the plurality of optical lenses (20, 40, 60, 80) are sequentially arranged in an axial direction, and wherein the plurality of optical lenses (20, 40, 60, 80) are configured such that by altering an axial position of one of the optical lenses (20, 40, 60, 80) from a first defined axial position to a second defined axial position, a final angular light distribution of the optical system (100) is variable.

A broken wheel detection system for detecting broken wheels on rail vehicles even when such vehicles are moving at a high rate of speed.

A broken wheel detection system for detecting broken wheels on rail vehicles even when such vehicles are moving at a high rate of speed.