Patent Grant
10093518
The present invention relates generally to a remote inspection of a passenger conveyor. In particular, the present invention relates to a remote inspection device and a method of performing a remote inspection for a passenger conveyor.
Currently, periodic visual inspection of an escalator is not only carried out through an on-site inspection by maintenance personnel, but is also carried out through a remote inspection using at least one camera mounted directly above the vicinity of an entrance of the escalator. By performing a remote inspection, external defects of the escalator can be quickly detected such as abnormal movements or damages of steps or handrails of the escalator, the presence of a foreign matter caught between a comb and steps of the escalator, etc.
When an operator at a remote maintenance center conducts a remote visual inspection, the operator first checks to see if there is no passenger on an escalator. Once the operator confirms that there is no passenger on the escalator, the operator manually switches the escalator's operation mode to an inspection mode which operates the escalator at a slower speed and performs a visual inspection through a video image of the escalator. If a passenger is getting on the escalator during the remote inspection, the operator switches the operation mode back to the normal operation mode manually.
However, due to the limitation of the camera view, the operator may not notice the presence of the passenger just before riding on the escalator. Furthermore, since there is a slight time delay in transmission of the video image until the passenger appears on a display of the remote controller, there is a chance that the passenger had already been on the escalator when the operator noticed the presence of the passenger approaching the escalator entrance. In such an instance, if the escalator operation is switched back to the normal operation mode, the speed of the escalator is suddenly changed, which may result in serious accidents.
Therefore, there exists in the art a need for providing an improved escalator remote inspection device capable of providing quick response to a passenger approaching an escalator entrance during a remote inspection.
According to one aspect of the present invention, a remote inspection device for a passenger conveyor is disclosed. The remote inspection device includes at least one camera mounted directly above the passenger conveyor for monitoring external conditions of the passenger conveyor, a remote controller for performing a remote visual inspection using the camera, a passenger conveyor controller for operating the passenger conveyor at a normal speed during a normal operation and for operating the passenger conveyor at a slower speed or bringing it to a complete stop during a remote visual inspection, and a sensor connected to the passenger conveyor controller and arranged in the vicinity of the entrance of the passenger conveyor for detecting the presence of a passenger approaching the entrance of the passenger conveyor.
The remote controller is connected to the passenger conveyor controller and the camera via remote access server. The passenger conveyor controller is configured to transmit a signal to the remote controller for interrupting the initiation of a remote visual inspection in response to the detection of a passenger approaching the entrance when initiating the remote visual inspection, and/or transmit a signal to the remote controller for interrupting the remote visual inspection and resume normal operation of the passenger conveyor in response to the detection of a passenger approaching the entrance during the remote visual inspection.
In some embodiments, the sensor includes a pair of sensors arranged in the vicinity of the entrance side of balustrades on either side of the passenger conveyor.
In some embodiments, each of the pair of sensors is oriented toward the approaching direction of a passenger and its detection range extends in a direction away from the passenger conveyor so that the sensor can detect a passenger in an area out of the camera's view.
In some embodiments, the sensor is arranged in a guidepost, a moving direction guide display or a guide fence disposed in a position spaced apart from the passenger conveyor.
In some embodiments, the sensor includes a Doppler sensor.
In some embodiments, the Doppler sensor includes a pair of Doppler sensors arranged in the vicinity of the entrance side of balustrades on either side of the passenger conveyor.
In some embodiments, each of the pair of Doppler sensors is oriented at a predetermined angle toward the centerline of the passenger conveyor so that the detection ranges of the pair of the Doppler sensors overlap with one another at a predetermined position away from the camera's view.
In some embodiments, the Doppler sensor is arranged to detect moving direction of a passenger approaching the entrance of the passenger conveyor.
In some embodiments, at least one camera is mounted directly above the entrance of the passenger conveyor.
According to another aspect of the present invention, a method of performing a remote inspection for a passenger conveyor is disclosed. The method includes monitoring the presence of a passenger approaching an entrance of the passenger conveyor using a sensor arranged in the vicinity of the entrance of the passenger conveyor, performing a remote visual inspection of external conditions of the passenger conveyor using at least one camera mounted directly above the passenger conveyor if no passenger is detected by the sensor, operating the passenger conveyor at a slower speed or bringing it to a complete stop during the remote visual inspection, and interrupting the remote visual inspection and resuming operation of the passenger conveyor at a normal speed if the sensor detects the presence of a passenger approaching the entrance during the remote visual inspection.
In some embodiments, performing a remote visual inspection further includes monitoring if a passenger appears in the camera's view, and the method further includes interrupting the remote visual inspection and resuming operation of the passenger conveyor at a normal speed if an operator finds a passenger appeared in the camera's view.
In some embodiments, the method further includes resuming the remote visual inspection and operation of the passenger conveyor at the slower speed if the sensor does not detect the presence of a passenger approaching the entrance for a predetermined period of time.
In some embodiments, resuming the remote visual inspection is performed if the sensor does not detect the presence of a passenger for one minute.
In some embodiments, resuming the remote visual inspection is performed manually.
In some embodiments, the sensor includes a pair of sensors arranged in the vicinity of the entrance side of balustrades on either side of the passenger conveyor.
In some embodiments, each of the pair of sensors is oriented toward the approaching direction of a passenger and its detection range extends in a direction away from the passenger conveyor so that the sensor can detect a passenger in an area out of the camera's view.
In some embodiments, the sensor is arranged in a guidepost, a moving direction guide display or a guide fence disposed in a position spaced apart from the passenger conveyor.
In some embodiments, the sensor includes a Doppler sensor.
In some embodiments, the Doppler sensor includes a pair of Doppler sensors arranged in the vicinity of the entrance side of balustrades on either side of the passenger conveyor.
In some embodiments, the Doppler sensor is arranged to detect moving direction of a passenger approaching the entrance of the passenger conveyor.
In some embodiments, at least one camera is mounted directly above the entrance of the passenger conveyor.
These and other aspects of this disclosure will become more readily apparent from the following description and the accompanying drawings, which can be briefly described as follows.
As shown in
Next, the remote visual inspection method of an escalator using the remote inspection device 1 in accordance with the present invention will be described.
If the sensor 6 does not detect the presence of a passenger at step 102, then the flow proceeds to step 103 where the operator 3 checks to see whether a passenger appears in the video image 10. If the operator 3 confirms that there is no passenger in the video image 10, flow proceeds to step 104 to initiate the remote inspection. In response to the initiation of the remote inspection at step 104, the remote controller 2 transmits a signal to the escalator controller 8 to operate the escalator 9 in the remote inspection mode, which drives the escalator 9 at a slower speed. Following the execution of step 104, flow returns to step 101 to proceed to the steps performed during the remote visual inspection.
During the remote inspection, the algorithm verifies that the escalator 9 is undergoing the remote inspection at step 101, followed by proceeding to step 106 where the controller 2 determines if the sensor 6 detects the presence of a passenger approaching the escalator 9 during the remote inspection.
If the sensor 6 detects the presence of a passenger approaching the escalator 9 at step 106, flow proceeds to step 108 to interrupt the remote inspection. At step 108, in response to the detection of the presence of a passenger at the escalator entrance, the escalator controller 8 sends a signal to interrupt the remote visual inspection to the remote controller 2 while resuming operation of the escalator 9 in the normal operation mode.
At step 108, the remote visual inspection may be resumed manually by the operator 3 if the operator 3 verifies that there is no passenger approaching the escalator entrance, followed by proceeding to step 101 to repeat process. Alternatively, it may be resumed automatically if the sensor 6 does not detect the presence of a passenger approaching the escalator 9 for a predetermined period of time, e.g., for one minute. The escalator operation may be switched back to the remote inspection mode when the remote inspection is resumed.
Again, at step 106, if the sensor 6 does not detect the presence of a passenger approaching the escalator 9 during the remote inspection, flow proceeds to step 107 where the operator 3 can check to see whether a passenger appears in the video image 10 while carrying out the remote inspection visually. If the operator 3 finds a passenger in the video image 10 at step 107 despite no detection of the passenger at step 106, it follows that a fault has occurred in one of the sensor systems. In the unlikely event that the fault has occurred in the sensor 6, the operator 3 can interrupt the remote inspection manually to operate the escalator 9 in the normal operation mode. If there is no passenger captured in the video image at step 107, i.e., if the remote inspection is not interrupted by the operator 3 manually, flow proceeds to step 101 to repeat process. This algorithm continues until the remote inspection is terminated by the operator 3.
With such a configuration, it is possible to appropriately perform switching of the escalator operation mode between the normal operation mode and the remote inspection mode during a remote visual inspection. Thus, the potential risk of a serious accident associated with sudden speed changes of the escalator can be avoided even if a passenger is getting on the escalator 9 during a remote inspection.
Using a Doppler sensor as the sensor 6 makes it possible to detect moving direction of a passenger approaching the escalator entrance with a simple device. In particular, a Doppler sensor can identify not only a passenger trying to enter from a side of the escalator entrance, but also a person just crossing the detection area 14 of the sensor 6. Thus, the detection efficiency of a passenger approaching the entrance during a remote inspection is improved and unwanted interruptions of remove inspection can be prevented.
Furthermore, since a Doppler sensor can detect the presence of a passenger approaching the escalator entrance over a relatively wide range in comparison with other sensor devices, the remote inspection device 1 can provide a quick switching of the escalator operation mode before the passenger reaches the escalator entrance. Especially, using a Doppler sensor is advantageous in that it enables a reliable detection of a passenger approaching the escalator entrance in an outdoor environment since a Doppler sensor is not influenced by sunlight and dust.
Although the present invention is described with referenced to the escalator 9, it should be understood that the present invention may be applied to any passenger conveyor such as a moving walkway.
While the present invention has been particularly shown and described with reference to the exemplary embodiments as illustrated in the drawings, it will be recognized by those skilled in the art that various modifications may be made without departing from the spirit and scope of the invention as disclosed in the accompanying claims.
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