JP2017100816A - Passenger conveyor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a passenger conveyor which prevents passengers from touching a high temperature hand rail and inhibits wastefulness of energy.SOLUTION: In a passenger conveyor 1, hand rails 10 are provided at left and right sides of footsteps and a hand rail belt 14 moves along a periphery part of each hand rail 10. The passenger conveyor 1 includes: a human presence sensor 34 which detects a human approaching the sensor; a pole 30 provided in front of the hand rail 10; and a cooling gas outlet 32 provided at the pole 30. When the human presence sensor 34 detects a human approaching, a cooling gas for cooling the hand rail belt 14 is sprayed from the cooling gas outlet 32 to the hand rail belt 14.SELECTED DRAWING: Figure 1

Description

  Embodiments of the present invention relate to passenger conveyors.

  A passenger conveyor installed outdoors may become so hot that it becomes difficult for the handrail belt to be illuminated by the sun during midsummer daytime.

  Then, when it is estimated that the temperature of the handrail belt is high, it has been proposed to cool the handrail belt using cold air in the truss erected on the upper floor side and the lower floor side (for example, Patent Document 1).

JP 2006-347669 A

  However, in such a passenger conveyor, the handrail belt continues to be cooled even when there are no passengers, which is a waste of energy.

  Then, this invention makes it a subject to provide the passenger conveyor which a passenger does not need to touch a hot handrail belt, and also does not use a waste of energy.

  In the passenger conveyor of the present embodiment, a balustrade is provided on both the left and right sides of the step, and a passenger sensor in which a handrail belt moves along a peripheral edge of the balustrade, a human sensor that detects that a person approaches, A pole provided in front of the balustrade and a cooling gas outlet provided in the pole, and when the human sensor detects a person approaching, the cooling gas outlet toward the handrail belt A cooling gas for cooling the handrail belt is blown.

Sectional drawing of the moving direction of the step 2 of the escalator 1 of embodiment. FIG. 3 is a cross-sectional view of the handrail belt 14 in the left-right direction. The block diagram of the escalator 1. FIG. Sectional drawing of the moving direction of the step 2 of the escalator 101 of the example of a change. Sectional drawing of the moving direction of the step 2 of the escalator 201 of another modification.

  Examples of passenger conveyors include escalators and moving walkways. In the following embodiments, the escalator 1 will be described as an example. In the following description, the left and right are expressions when the escalator 1 is viewed from the front, that is, from the moving direction.

  FIG. 1 shows a cross-sectional view of an escalator 1 according to this embodiment. Trusses 20 are installed on the upper and lower floors of the building. Step drive sprockets 21 and 22 are arranged inside the upper floor machine room 25 and the lower floor machine room 26 of the truss 20, respectively. An endless step drive chain 23 is wound around the step drive sprockets 21 and 22. The step drive sprocket 21 on the upper floor side is connected to a drive device 24 having a motor and a speed reducer, and rotates by driving of the drive device 24. This rotation drives the step drive chain 23 and the other step drive sprocket 22. A step 2 as a riding portion is connected to the step drive chain 23 at equal intervals without any gap. When the step drive chain 23 is driven, the step 2 connected thereto circulates between the upper floor side and the lower floor side along a guide rail (not shown). A control unit 27 that controls the operation of the escalator 1 is provided inside the machine room 25.

  On the left and right sides of the escalator 1, a balustrade 10 is erected from the upper floor to the lower floor. A handrail belt drive sprocket 12 is provided inside the truss 20. An endless handrail belt drive chain 13 is wound around the step drive sprocket 21 and the handrail belt drive sprocket 12. A handrail belt 14 is hung on the periphery of the balustrade 10 and the handrail belt drive sprocket 12. When the step drive sprocket 21 rotates, the handrail belt drive chain 13 and the handrail belt drive sprocket 12 are driven, and the handrail belt 14 circulates between the upper floor side and the lower floor side along the periphery of the balustrade 10. To do. The handrail belt 14 moves in synchronization with the movement of the step 2. The lower part of the balustrade 10 is covered with a skirt portion 11 provided from the upper floor to the lower floor. An inlet portion 3 is formed on each of the upper floor side and the lower floor side of the skirt portion 11. The handrail belt 14 passes through the inside of the inlet portion 3 and enters the skirt portion 11 or goes out of the skirt portion 11. Therefore, the shape of the inlet portion 3 is a shape that matches the cross-sectional shape of the handrail belt 14.

  The handrail belt 14 is formed in a ring shape by connecting both longitudinal ends of a long belt body. As shown in FIG. 2, the cross-sectional shape of the handrail belt 14 in the left-right direction is a C-shape that opens downward. A handrail deck 15 is fixed to the periphery of the balustrade 10, and a handrail belt 14 is provided so as to wrap the handrail deck 15. The handrail belt 14 is usually moving at a speed of 2 to 3 m / second, but may change to a speed outside this range when the amount of passengers is large or small.

  A pole 30 is provided on the escalator 1 entry side in front of the balustrade 10 (in front of the person trying to enter the escalator 1). A cooling gas blowing port 32 is provided in a portion of the pole 30 on the balustrade 10 side. The cooling gas outlet 32 is desirably below the height of the center P of rotation of the handrail belt 14 at the boarding side end of the balustrade 10. The cooling gas outlet 32 can be opened and closed by a valve 33. The pole 30 is provided with a human sensor 34 for detecting a person approaching. The human sensor 34 may be a general sensor that can detect a person when the person approaches, one that detects a person with infrared rays, one that detects a person with ultrasonic waves, one that detects a person with visible light, What detects a person with infrared rays and an ultrasonic wave, etc. are mentioned. The human sensor 34 detects the person when the person approaches the human sensor 34 to a distance of, for example, 1 to 3 m. The pole 30 may be provided with a display unit 36 that displays the moving direction of the escalator 1 and the like. The pole 30 is also provided with an outside air temperature sensor 38 for measuring the outside air temperature. However, the human sensor 34 and the outside air temperature sensor 38 may be provided at a place other than the pole 30.

  In FIG. 1, the pole 30 is provided only on the upper floor side as the boarding side, but when both the upper floor side and the lower floor side can be the boarding side, the pole 30 is provided on both the upper and lower floors, Are provided with a cooling gas outlet 32 and the like.

  The machine room 25 is provided with a liquid nitrogen tank 40, and a heater 42 is provided in a part of the liquid nitrogen tank 40. Although liquid nitrogen is stored in the liquid nitrogen tank 40, the means until the storage is not limited. The liquid nitrogen to be stored is manufactured, for example, by a liquid nitrogen manufacturing apparatus (not shown) provided adjacent to the escalator 1 and is transported to the liquid nitrogen tank 40 through a pipe and stored.

  As shown in FIG. 3, the control unit 27 is electrically connected to the outside air temperature sensor 38, the human sensor 34, the heater 42 of the liquid nitrogen tank 40, the valve 33 of the cooling gas outlet 32, and the display unit 36. Yes. The control unit 27 performs control as follows.

  First, the outside air temperature sensor 38 constantly measures the outside air temperature. Then, when the outside air temperature becomes equal to or higher than a predetermined temperature, the control unit 27 starts the handrail cooling operation. When the handrail cooling operation is started, the control unit 27 first makes the human sensor 34 in a detectable state and energizes the heater 42 of the liquid nitrogen tank 40 to generate nitrogen gas as a cooling gas from the liquid nitrogen.

  When the human sensor 34 detects a person approaching during the handrail cooling operation, the control unit 27 opens the valve 33 of the cooling gas outlet 32 and continues the cooling gas from the pole 30 toward the handrail belt 14 for a certain period of time. And spray. Here, the blowing of the cooling gas may be started immediately after the human sensor 34 detects a person. However, when the human sensor 34 detects a far person, it takes time for the person to enter the escalator 1 after the human sensor 34 detects the person. In such a case, the cooling gas spraying may be started after a predetermined time has elapsed after the human sensor 34 detects a person. The specific length of the predetermined time varies depending on how far the human sensor 34 can detect a person, but for example, the cooling gas is required before a person with an average walking speed reaches 1 m before the balustrade 10. Is set to start. Further, the length of time for which the spraying is performed is a length set in advance as a time necessary for cooling the range before and after the portion of the handrail belt 14 touched by the passenger.

  When the cooling gas is sprayed, the cooling gas hits the surface of the handrail belt 14 and the temperature of the portion decreases. A person who gets on the escalator 1 touches the portion where the temperature of the handrail belt 14 is lowered. After the cooling gas is blown for a predetermined time, the control unit 27 closes the valve 33 and keeps the valve 33 closed until the human sensor 34 detects a person approaching again. Whenever the human sensor 34 detects an approaching person, the control unit 27 opens the valve 33 and blows the cooling gas onto the handrail belt 14. When the outside air temperature becomes lower than a preset constant temperature, the control unit 27 ends the handrail cooling operation. While the control unit 27 is performing the handrail cooling operation, or while the control unit 27 is spraying the cooling gas toward the handrail belt 14, this is displayed on the display unit 36.

  In the above embodiment, since the surface of the handrail belt 14 is cooled by the cooling gas, the passenger does not have to touch the handrail belt 14 in a high temperature state. In addition, since the handrail belt 14 is cooled only when a person approaches, there is no waste of energy. Moreover, since the cooling gas outlet 32 is provided in the pole 30 in front of the balustrade 10, the cooling gas can be blown from the front toward the handrail belt 14 to cool the handrail belt 14 efficiently. The pole 30 originally provided for displaying the moving direction of the escalator 1 can be effectively used.

  Further, if the handrail cooling operation is performed only while the outside air temperature is equal to or higher than a certain temperature as in the present embodiment, the handrail belt 14 is cooled until the outside air temperature is low and the temperature of the handrail belt 14 is difficult to rise. Is not performed and energy is not wasted.

  In addition, while the control unit 27 is performing the handrail cooling operation, or while the control unit 27 is performing the handrail cooling operation and actually blowing the cooling gas toward the handrail belt 14, the fact is displayed. If it is displayed at 36, the passenger can feel that the handrail belt 14 is not hot and can touch the handrail belt 14 with peace of mind.

  Further, if the cooling gas outlet 32 is below the height of the center P of rotation of the handrail belt 14 at the end of the balustrade 10 on the boarding side, there is no possibility that the cooling gas directly hits the passenger.

  Various modifications can be made to the above embodiment. In FIGS. 4 and 5 showing the escalators 101 and 201 of the modified example, the same members as those in the above embodiment are denoted by the same reference numerals as those in FIG.

  First, as shown in FIG. 4, a speed measuring device 31 that measures the speed of a person approaching the passenger conveyor may be provided at a place on the escalator 1 on the boarding side, for example, the pole 30. Then, based on the speed measured by the speed measuring device 31, the time from when the human sensor 34 detects the approach of a person until the cooling gas spraying is started is determined. The speed measuring device 31 is electrically connected to the control unit 27. In this modified example, when the human sensor 34 detects the approach of a person, the speed at which the speed measuring device 31 approaches is measured. When the speed at which the person approaches is fast, the control unit 27 starts spraying the cooling gas immediately or after a short period of time has elapsed. On the other hand, when the speed at which the person approaches is slow, the control unit 27 starts spraying the cooling gas after elapse of a certain time (however, a longer time than the certain time when the speed at which the person approaches is high). The speed measuring device 31 measures, for example, a reflected wave of an electromagnetic wave irradiated toward a person. According to this modified example, the cooling gas spraying is not delayed when the approaching speed of the person is fast, and the cooling gas starts too early when the approaching speed of the person is slow. There is no waste.

  Further, in the above embodiment, the handrail cooling operation is started when the outside air temperature is equal to or higher than a certain temperature, but the handrail cooling operation is started when the temperature of the handrail belt 14 is not less than the outside air temperature and is not less than a certain temperature. May be. Specifically, a handrail temperature sensor 35 is provided in any location of the balustrade 10 or in the skirt portion 11 (a state in which the handrail temperature sensor 35 is provided in the balustrade 10 is shown in FIG. 4. ) The handrail temperature sensor 35 is in contact with the handrail belt 14 or is disposed in the vicinity thereof. Alternatively, a simulated member having the same color and material as the handrail belt 14 may be provided in a place exposed to sunlight, and the handrail temperature sensor 35 may be embedded in the simulated member. When the handrail temperature sensor 35 is provided as described above, the handrail temperature sensor 35 can directly or indirectly measure the temperature of the handrail belt 14. And the control part 27 will start said handrail cooling operation, if the temperature which the handrail temperature sensor 35 measures becomes more than fixed temperature. The constant temperature here is a temperature that a person feels hot when touching the handrail belt 14 at that temperature, and is a preset temperature. According to this, since the handrail cooling operation is performed only when the handrail belt 14 is actually hot, waste of energy does not occur.

  Further, both the outside air temperature sensor 38 and the handrail temperature sensor 35 are provided, and the control unit 27 may start the handrail cooling operation when at least one of the temperatures becomes equal to or higher than a certain temperature.

  Further, when the outside air temperature or the temperature of the handrail belt 14 becomes a certain temperature or higher, the control unit 27 does not start the handrail cooling operation, but is a daytime period of a certain period in summer (for example, 13 in a certain period including August). The control unit 27 may start the handrail cooling operation at a time zone including -14: 00). According to this, it is not necessary to provide a temperature sensor in the escalator 1, and the control of the escalator 1 is easy.

  Further, the control unit 27 may start the handrail cooling operation when the daytime time zone (for example, a time zone including 13 to 14:00) is reached throughout the year without being limited to the summer season. Further, the control unit 27 may start the handrail cooling operation in the summer (for example, a certain period including August) without limiting the time zone.

  Further, as shown in FIG. 4, the pole 30 is provided with a plurality (two in the illustrated case) of cooling gas outlets 32a and 32b, and these cooling gas outlets 32a and 32b are arranged in the vertical direction. Also good. Both of the two cooling gas outlets 32a and 32b are preferably below the height of the rotation center P of the handrail belt 14 at the boarding side end of the balustrade 10. In the case of this modified example, since the cooling gas is sprayed onto the handrail belt 14 at a plurality of locations, the handrail belt 14 is reliably cooled.

  Further, as shown in FIG. 5, in addition to the cooling gas outlet 32, the pole 30 may be provided with a disinfecting liquid outlet 32 c that sprays the disinfectant liquid in the form of a mist toward the handrail belt 14. In this case, it is desirable that the control unit 27 simultaneously perform the blowing of the cooling gas from the cooling gas blowing port 32 and the blowing of the disinfecting solution from the disinfecting solution blowing port 32c. That is, it is desirable that the disinfectant is controlled to be sprayed onto the handrail belt 14 while the cooling gas is sprayed. In this case, only the portion of the handrail belt 14 that is touched by a person is sterilized efficiently.

  The cooling gas is not limited to nitrogen gas generated from liquid nitrogen. For example, a dry ice storage chamber may be provided in the machine room 25 instead of the liquid nitrogen tank 40, and cold air generated therefrom may be used as the cooling gas. Moreover, the air conditioning provided with a compressor, an evaporator, and a condenser may be provided, and the cold air | gas generated from there may be used as cooling gas. The cooling gas may be any gas that can cool the handrail belt 14 from a temperature at which a person feels hot (for example, 45 to 55 ° C.) to a temperature at which it feels not hot (for example, 30 to 40 ° C.).

  The above embodiment is an illustration and the scope of the invention is not limited to this. The above embodiments can be implemented in various other forms, and various omissions, substitutions, and changes can be made without departing from the scope of the invention. The above embodiments and modifications thereof are included in the inventions described in the claims and their equivalents.

DESCRIPTION OF SYMBOLS 1 ... Escalator, 2 ... Step, 3 ... Inlet part, 10 ... Railing, 11 ... Skirt part, 12 ... Handrail belt drive sprocket, 13 ... Handrail belt drive chain, 14 ... Handrail belt, 15 ... Handrail deck, DESCRIPTION OF SYMBOLS 20 ... Truss, 21 ... Step drive sprocket, 22 ... Step drive sprocket, 23 ... Step drive chain, 24 ... Drive device, 25 ... Machine room, 26 ... Machine room, 27 ... Control part, 30 ... Pole, 31 ... Speed Measuring instrument 32, 32a, 32b ... Cooling gas outlet, 32c ... Disinfectant outlet, 33 ... Valve, 34 ... Human sensor, 35 ... Handrail temperature sensor, 36 ... Display, 38 ... Outside air temperature sensor, 40 ... Liquid nitrogen tank, 42 ... Heater, 101 ... Escalator, 201 ... Escalator

In the passenger conveyor of the present embodiment, a balustrade is provided on both the left and right sides of the step, and a passenger sensor in which a handrail belt moves along the peripheral edge of the balustrade, a human sensor that detects that a person approaches, A pole provided in front of the balustrade and a cooling gas outlet provided in the pole, and when the human sensor detects a person approaching, the cooling gas outlet toward the handrail belt Cooling gas for blowing the handrail belt is blown , and a speed measuring device for measuring the speed of the person approaching the passenger conveyor is provided, based on the speed measured by the speed measuring device, The time from when the human sensor detects the approach of a person to when the cooling gas starts to be sprayed is determined .

Claims (10)

In the passenger conveyor where balustrades are provided on both the left and right sides of the steps, and the handrail belt moves along the periphery of the balustrade,
A human sensor for detecting that a person has approached, a pole provided in front of the balustrade, and a cooling gas outlet provided in the pole, and when the human sensor detects the approach of a person, A passenger conveyor on which cooling gas for cooling the handrail belt is blown from the cooling gas outlet toward the handrail belt.   An outside air temperature sensor for measuring outside air temperature is provided, and when the temperature sensor detects the approach of a person when the temperature measured by the outside air temperature sensor is equal to or higher than a certain value, the cooling gas outlet port faces the handrail belt. The passenger conveyor according to claim 1, wherein the cooling gas is sprayed.   A handrail temperature sensor for measuring the temperature of the handrail belt; and when the human sensor detects the approach of a person when the temperature measured by the handrail temperature sensor is equal to or higher than a certain value, The passenger conveyor according to claim 1 or 2, wherein the cooling gas is blown toward a handrail belt.   A speed measuring device for measuring the speed of a person approaching the passenger conveyor is provided, and the human sensor detects the approach of the person based on the speed measured by the speed measuring device. The passenger conveyor according to any one of claims 1 to 3, wherein a time until the cooling gas blowing is started is determined.   The passenger conveyor according to any one of claims 1 to 4, wherein a plurality of the cooling gas outlets are arranged in the pole in the vertical direction.   The passenger conveyor according to any one of claims 1 to 5, wherein a disinfecting liquid outlet is provided in the pole, and the disinfecting liquid is sprayed from the disinfecting liquid outlet toward the handrail belt.   The passenger conveyor according to claim 6, wherein spraying of the cooling gas from the cooling gas outlet and spraying of the disinfecting liquid from the disinfectant outlet are simultaneously performed.   The passenger conveyor according to any one of claims 1 to 7, wherein the cooling gas outlet is below a center height of rotation of the handrail belt at the boarding side end of the balustrade.   The display part is provided in the said pole, and while the said cooling gas is sprayed on the said handrail belt from the said cooling gas blower outlet, that is displayed on the said display part. The passenger conveyor according to item.   The passenger conveyor according to any one of 1 to 9, wherein the cooling gas is nitrogen gas generated from liquid nitrogen.

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