The present invention relates to an apparatus configured to detect abnormality in a drive system for steps based on a posture of a step of a passenger conveyor.
Hitherto, a gap is defined between each of steps and each of skirt guards of a passenger conveyor so as to prevent contact of each of the steps with the skirt guards at the time of traveling. Each of the steps is caused to travel along a traveling direction thereof by step chains which are arranged on both side surfaces of each of the steps. In some cases, each of the step chains is extended due to a temporal change or an external factor. When the step chains are not evenly extended, in some cases, each of the steps may travel while being inclined with respect to the traveling direction. In such a case, the side surfaces of each of the steps may be brought into contact with the skirt guards and cause damage on the skirt guard.
In view of the circumstance described above, there has been disclosed an apparatus having the following configuration. Specifically, at a position at which step horizontally move and at which postures of the steps are not corrected, a distance sensor configured to measure a distance to a side surface of the step is disposed, and a change in width of a gap between the steps is measured based on measurement values given by the distance sensor, to thereby detect extension of chains for the steps (for example, see Patent Literature 1). Moreover, there has been disclosed an apparatus having the following configuration. Specifically, sensors are arranged on one end side and another end side of a landing plate, and it is determined that inclination of a step surface is abnormal when a time difference in passage of the step surface through the sensors exceeds a threshold value (for example, see Patent Literature 2).
[PTL 1] JP 2006-273549 A
[PTL 2] JP 2016-16926 A
In the apparatus described in Patent Literature 1, the extension of the step chains is detected based only on a change in gap between the steps. However, the change in gap between the steps is not caused only by the extension of the step chains. Moreover, even when the step chains are extended, the change in gap between adjacent steps is small, and hence the extension of the step chains cannot accurately be detected based on the change in gap between the steps. Moreover, in the apparatus of Patent Literature 2, the sensors are arranged on both the right and left sides of the landing plate. However, in general, at the position of the landing plate, a position of the step is regulated in order to avoid contact between the step and a comb portion. Therefore, at the position of the landing plate, abnormality of the step cannot accurately be detected.
The present invention has been made to solve the problems described above, and obtains an abnormality detection apparatus for a passenger conveyor which is configured to detect wear of guide members of a step and extension of step chains based on a temporal change in traveling state of the step at an upper horizontal portion and a lower horizontal portion.
According to one embodiment of the present invention, there is provided an abnormality detection apparatus for a passenger conveyor, including: a first sensor arranged at an upper horizontal portion; a second sensor arranged at a lower horizontal portion; and a control device configured to receive respective outputs of the first sensor and the second sensor, wherein the first sensor and the second sensor are each configured to measure a distance to a side surface of each of steps along a traveling direction of each of steps, and wherein the control device is configured to detect abnormality of the passenger conveyor based on a change amount of each of measurement values given by the first sensor and the second sensor.
According to the present invention, a traveling state of a step and a change in traveling state are detected based on a posture of the step at an upper horizontal portion and a posture of the step at a lower horizontal portion. With this, abnormality of guide members and step chains can be detected.
Now, an abnormality detection apparatus for a passenger conveyor according to a preferred embodiment of the present invention is described with reference to the drawings.
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As illustrated in
When the passenger conveyor performs an operation of moving upward in a traveling direction F indicated by the arrows illustrated in
As illustrated in
As illustrated in
The distance sensor 15A is arranged on one side in the direction perpendicular to the traveling direction F of each of the steps 6 so as to be apart from a side surface of each of the steps 6 by a certain distance. Moreover, the distance sensor 15B is arranged on another side in the direction perpendicular to the traveling direction F of each of the steps 6 so as to be apart from each of the steps 6 by a certain distance. The distance sensors 15A and 15B are each constituted of a non-contact sensor such as an optical reflection type sensor or an ultrasonic sensor. The distance sensors 15A and 15B are configured to simultaneously measure the distances to the side surfaces of the same step 6 in a continuous manner or an intermittent manner during traveling.
The distance sensors 15A and 15B are fixed to the truss 1 (not shown) while being located apart from each other in the traveling direction F within a range in which the distances to the side surfaces of the same step 6 can simultaneously be measured. As described above, through the simultaneous measurement of the distances to the side surfaces of the same step 6 with use of the distance sensors 15A and 15B being arranged apart from each other in the traveling direction F, inclination of each of the steps 6 in a horizontal plane and a positional deviation amount of each of the steps 6 in the direction perpendicular to the traveling direction F are detected. At the lower horizontal portion B, there are arranged distance sensors 16A and 16B similarly to the distance sensors 15A and 15B arranged at the upper horizontal portion A.
Next, with reference to
In
When the guide member 6f of the step 6 is worn by the sliding on the driving rail 10, or the guide member 6g of the step 6 is worn by the sliding on the skirt guard 13, as illustrated in
For example, when the passenger conveyor performs an operation of moving upward, in a case in which, with regard to the same step 6, a measurement value given by the distance sensor 16A at the lower horizontal portion B is large, and a measurement value given by the distance sensor 15A at the upper horizontal portion A is small, it can be understood that each of the steps 6 obliquely travels so as to approach the distance sensor 15A as proceeding from the lower horizontal portion B toward the upper horizontal portion A.
In contrast, with regard to the same step 6, in a case in which the measurement value given by the distance sensor 16A at the lower horizontal portion B is small, and the measurement value given by the distance sensor 15A at the upper horizontal portion A is large, it can be understood that each of the steps 6 obliquely travels so as to separate from the distance sensor 15A as proceeding from the lower horizontal portion B toward the upper horizontal portion A.
Moreover, when the measurement value given by the distance sensor 16A at the lower horizontal portion 3 and the measurement value given by the distance sensor 15A at the upper horizontal portion A are substantially equal to each other, it can be understood that each of the steps 6 travels substantially straight along the traveling direction F.
As an initial setting of the abnormality detection apparatus, measurement values of distances to the side surfaces of each of the steps 6 measured with use of the distance sensors 15A, 15B, 16A, and 16B under a state in which each of the steps 6 is not deviated in position and is not inclined are each set to the reference value D0. Moreover, for example, threshold values of ±1 mm are set to the temporal change amount of each of the measurement values given by the distance sensors 15A, 15B, 16A, and 16B. Then, with use of the control device 17, a change amount of each of measurement values given by the distance sensors 15A, 15B, 16A, and 16B is compared with the threshold values. Then, the control device 17 determines that abnormality has occurred when a traveling position of each of the steps 6 is changed to be equal to or larger than the threshold value due to wear of the each of the guide members 6f and 6g or uneven extension of the two step chains 5.
When the guide member 6f or 6g is worn, each of the steps 6 travels at a position deviated in the direction perpendicular to the traveling direction F while maintaining an initial tendency of traveling. Moreover, when the two step chains 5 are unevenly extended, each of the steps 6 travels in a state of being inclined with respect to the traveling direction F, to thereby obliquely travel with respect to the initial tendency of traveling. With this, based on a change amount of each of the measurement values given by the distance sensors 15A and 15B at the upper horizontal portion A and the distance sensors 16A and 16B at the lower horizontal portion 3, a cause of abnormality can be estimated.
When a passenger stands on the step 6, the step 6 may be forced to move rightward and leftward in some cases. Therefore, it is preferred that the measurement of the distances to the side surfaces of the step 6 with use of the distance sensors 15A, 15B, 16A, and 16B be performed by circulating the passenger conveyor several times at the time when no load is applied, such as during a period other than operation hours of the passenger conveyor. Then, for example, a maximum value, a minimum value, and an average value of the measurement values may be calculated and accumulated. Moreover, when the measurement is continuously performed, a measurement value of a clearance between adjacent steps 6 becomes larger, and hence the measurement value of the clearance of each of the steps 6 is not to be included in the measurement values to be accumulated. However, borders of the steps 6 can be detected based on the measurement values of the clearances of the steps 6, and hence the measurement values of the clearances may be used to count the number of steps 6.
As described above, according to the abnormality detection apparatus for a passenger conveyor of the first embodiment, the distance sensor 15A and the distance sensor 15B are arranged at the upper horizontal portion A so as to be apart from each other along the traveling direction F of the step 6, and the distance sensor 16A and the distance sensor 16B are arranged at the lower horizontal portion B so as to be apart from each other along the traveling direction F of the step 6. Further, based on the change amount of each of the measurement values given by the distance sensors 15A, 15B, 16A, and 16B, the positional deviation of the step 6 in the direction perpendicular to the traveling direction F and the inclination of each of the steps 6 in the horizontal plane are detected. Furthermore, with use of the control device 17, each of the measurement values given by the distance sensors 15A, 15B, 16A, and 16B is compared with the threshold values, to thereby determine presence or absence of abnormality and a cause of the abnormality. With this, wear of the guide members 6f and 6g of the passenger conveyor and uneven extension of the two step chains 5 can be detected, thereby being capable of achieving rationalization of maintenance work.
In the first embodiment, description is made of the example case in which the passenger conveyor performs the operation of moving upward. However, a similar effect can be attained also in a case of performing an operation of moving downward. Moreover, in the first embodiment, the distance sensors 15A and 15B are arranged so as to be opposed to each other in the direction perpendicular to the traveling direction of the step 6, and the distance to the side surface of the step 6 on one side and the distance to the side surface of the step 6 on another side are measured. However, the arrangement of the distance sensors 15A and 15B is not limited to this. For example, the distance sensors 15A, and 15B may be arranged in the same direction perpendicular to the traveling direction of the step 6, to thereby measure the distance to the same side surface. With such a configuration, when each of the steps 6 is deviated in position in the direction perpendicular to the traveling direction F, measurement values given by the distance sensors 15A and 15B may have such a change of being similarly large or being similarly small. Further, when each of the steps 6 is inclined with respect to the traveling direction F, measurement values given by the distance sensors 15A and 15B may be such that one of the measurement values become larger and another of the measurement values become smaller.
In the first embodiment, the two distance sensors 15A and 15B are arranged at the upper horizontal portion A, and the two distance sensors 16A and 16B are arranged at the lower horizontal portion B. However, when measurement is continuously performed, one distance sensor may be arranged at each of the upper horizontal portion A and the lower horizontal portion B. In this case, at each of the upper horizontal portion A and the lower horizontal portion B, an end-to-end distance of the side surface of one step 6 is continuously measured, and the positional deviation of the step 6 in the direction perpendicular to the traveling direction F and the inclination of the step 6 in the horizontal plane can be detected based on a tendency of the change in measurement values.
1 truss, 2 control panel, 3 drive unit, 4 step sprocket, 5 step chain, 6 step, 6a step surface, 6b riser, 6c step shaft, 6d driving roller, 6e trailing roller, 6f, 6g guide member, 7 lower reversing portion, 8 balustrade, 9 moving handrail, 10 driving rail, 11 trailing rail, 12 comb portion, 13 skirt guard, 14 side roller, 15A, 15B distance sensor (first sensor, upper sensor), 16A, 16B distance sensor (second sensor, lower sensor), 17 control device, 18 alarming device
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/026075 | 7/19/2017 | WO | 00 |