JP2015003793A - Elevator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To control a ventilation valve so that a passenger in a car does not have a lack of oxygen in an elevator that includes the car having an airtight structure.SOLUTION: An elevator 20 includes: a car 10; air tightness adjustment means 5 for adjusting atmospheric pressure within the car 10; a door switch 2 for detecting opening/closing of a door 11 of the car; a load sensor 4 for detecting a load of the car; a ventilation valve 6 for ventilating inside of the car; and an elevator control device 1 for controlling lifting/lowering of the car. The air tightness adjustment means estimates a carbon dioxide gas concentration within the car when the car reaches a target floor by using an actual measurement value of door opening/closing time detected by the door switch, the load detected by the load sensor, the volume of the car and an operation signal transmitted from the elevator control device. When the estimated value exceeds a predetermined reference value, the car is stopped on the nearest floor and is ventilated by opening the car or by opening the ventilation valve.

Description

  The present invention relates to an elevator having a car that can be hermetically controlled, and more particularly to an elevator that hermetically controls a car using a ventilation valve.

  In long-distance / ultra-high-speed elevators, the pressure fluctuation per unit time in the car is large. The passengers in such a long-stroke / super-high-speed elevator car may be clogged or dizzy due to large air pressure fluctuations. In order to eliminate this discomfort, it has been proposed to control the atmospheric pressure in the car.

  By the way, in order to control the atmospheric pressure in the car, it is necessary to improve the airtightness of the car. However, if the car has an airtight structure, if a power failure or the like occurs and the return is delayed, the passenger will be confined in the car for a long time. In that case, ventilation in the car is not possible and passengers may run out of oxygen.

  Therefore, Patent Document 1 describes that an elevator having a highly airtight passenger car automatically opens and closes a ventilator when a power failure occurs. The elevator ventilator described in this publication has a ventilation window opening / closing member that is opened for ventilation in the event of a power failure, and a solenoid for locking that locks the closed ventilation window opening / closing member that is energized during normal times. The locking solenoid shaft is retracted to provide door opening force.

JP 2011-57414 A

  In the elevator ventilator described in Patent Document 1, the shaft of the locking solenoid is retracted during a power failure to open the ventilation window. However, in the ventilation device described in this publication, there is no disclosure about a case where the elevator breaks down due to an unexpected situation while the power is on, and the car remains closed. In other words, as a result of the inability to open the doors of the car and the opening of the ventilation window, the occurrence of malfunctions in which the carbon dioxide concentration increases due to the exhalation of passengers and the car becomes oxygen deficient is completely considered. Not.

  Moreover, in the ventilation apparatus described in Patent Document 1, it is necessary to energize the solenoid to close the ventilation window, and the solenoid is always energized. Therefore, even when there are no passengers in the car and it is not necessary to keep the car airtight, the solenoid is energized and the ventilation window is closed, which consumes unnecessary power and is uneconomical. . On the other hand, since the ventilation window is opened only at the time of a power failure, the normality / abnormality of the solenoid that controls the opening and closing of the ventilation window can be determined only at the time of a power failure, and the soundness of the ventilation device cannot always be determined in advance.

  The present invention has been made in view of the above-mentioned problems of the prior art, and its purpose is to predict the lack of oxygen in the car in an airtight state while the car is operating, and to prevent the passenger from being deficient in oxygen. There is to do.

  In order to achieve the above object, the present invention is characterized by airtight controllable vehicles, airtight adjusting means for adjusting the airtightness in the car according to the up and down stroke and speed of the car, and the car. Door opening / closing detection switch for detecting opening / closing of the door, a load sensor for detecting the load of the car, a ventilation valve for making the inside of the car airtight or opening the airtightness, and controlling the raising / lowering of the car The elevator control device transmits an operation signal of the car to the airtight adjustment means, and the airtight adjustment means measures the door opening / closing time detected by the door open / close detection switch. Using the value, the load data detected by the load sensor, the volume of the car and the operation signal transmitted from the elevator control device. Estimate the carbon dioxide gas concentration or oxygen gas concentration in the car when the car arrives at the destination floor, and if the estimated gas concentration in the destination floor is outside the predetermined reference range, move the car to the nearest floor. To stop and open the car door to ventilate or to open the normally open vent valve to ventilate.

  According to the present invention, since the elevator can estimate the carbon dioxide or oxygen concentration in the car, it is possible to predict an oxygen deficiency state in the car in an airtight state while the car is operating, and to ensure that the passenger is deficient in oxygen. Can be prevented.

It is a longitudinal section of one example of an elevator concerning the present invention. It is a perspective view of the periphery of the car which the elevator shown in FIG. 1 has. It is a block diagram of the airtight car ventilation control apparatus which the elevator shown in FIG. 2 has.

  Hereinafter, an embodiment of an elevator according to the present invention will be described with reference to FIGS. 1 to 3. FIG. 1 is a longitudinal sectional view of an embodiment of the elevator 20. FIG. 2 is a perspective view around the car 10 of the elevator 20 shown in FIG. 1, and FIG. 3 shows an airtight car ventilation control device (airtight adjusting means) 5 for controlling the ventilation valve 6 attached to the car 10. It is a block diagram.

  In FIG. 1, a plurality of sheaves 23 are attached to an upper portion in a hoistway 22 where the car 10 moves up and down, and a main rope 25 is wound around the sheave 23. A counterweight 24 is attached to one end side of the main rope 25. The car 10 is provided with a sheave, and the main rope 25 is wound around the sheave. The counterweight 24 reduces the power when the car 10 is raised and lowered.

  A drive motor 27 that drives the main rope 25 is disposed on the bottom surface of the hoistway 22. Although not shown, each floor 28 on the landing side is provided with a landing-side opening / closing door that opens and closes in synchronization with a car-side opening / closing door (car door) arranged in front of the car 10. It is like that. Further, an elevator control device 1 for controlling the entire elevator 20 including the car 10 is also provided in the hoistway 22.

  A car 10 shown in FIG. 2 is a car for a long process / ultra-high speed elevator and has an airtight structure. That is, the pressure regulators 12A and 12B for adjusting the air pressure in the car are provided on the upper surface of the car 10 of the elevator 20, and the ventilation valve 6 for ventilating the air in the car 10 on the side of the car 10 and A ventilation valve drive SW 61 for detecting the closed state of the ventilation valve 6 is provided. Further, a carbon dioxide concentration sensor 3 for detecting the carbon dioxide concentration in the car 10 is provided on the upper surface of the car 10. A load sensor 4, which will be described in detail later, is attached to the bottom surface of the car 10.

  Here, the air pressure adjusters 12A and 12B are two fans, and they face each other so that a large amount of air can be instantaneously discharged from the car 10 or introduced into the car 10. The ventilation valve 6 is driven by an actuator (not shown) and is attached to the outer surface of the car 10. Then, as indicated by an arrow in FIG. 1, the car 10 is pivoted outwardly around the upper end portion to open and close, thereby ventilating the air in the car 10. The ventilation valve 6 is set to an open state when the actuator is not energized. That is, it is set to normally open.

  An airtight car ventilation control device 5 that controls the pressure regulators 12A and 12B and the ventilation valve 6 and receives the detection result of the carbon dioxide sensor 3 is disposed on the upper surface of the car 10. The airtight car ventilation control device 5 is connected to a door switch 2 provided near the car door 11 (upward in FIG. 2) in order to detect opening and closing of the car door 10 (car door). ing.

  Next, ventilation control in the car 10 of the elevator 20 configured as described above will be described with reference to the block diagram shown in FIG. The elevator control device 1 is provided with an airtight car ventilation control device 5. The airtight car ventilation control device 5 includes a door open / close time detection unit 51 that detects the open / close time of the car door 11 of the car 10.

  The door opening / closing time detection unit 51 receives a detection signal 121 of the door switch 2 that is turned on / off when the car door 11 is opened and closed, and calculates the duration of time when the car 10 is closed by the car door 11. To do. The detection signal 2 of the door switch is also input to the elevator control device 1.

  The airtight car ventilation control device 5 includes a sensor signal processing unit 52. The sensor signal processing unit 52 receives the carbon dioxide concentration signal 122 in the car 10 detected by the carbon dioxide concentration sensor 3 and the load signal 123 in the car 10 measured by the load sensor 4. The load signal 123 is converted by the sensor signal processing unit 25 into the number of passengers in the car 10 or the expiratory volume of the passengers.

  The door opening / closing time signal 124 obtained by the door opening / closing time detecting unit 51 and the signal 125 of the carbon dioxide concentration and the load in the car 10 obtained by processing by the sensor signal processing unit 52 are sent to the ventilation time calculating unit 53. Entered. The ventilation time calculation unit 53 calculates the ventilation timing based on these signals 124 and 125.

  A timing signal 126 for ventilating the inside of the car 10 obtained by the ventilation time calculation unit 53 is input to the ventilation valve opening / closing control unit 54. An information signal 111 regarding the operation of the car 10 is also input from the elevator control device 1 to the ventilation valve opening / closing control unit 54, and the ventilation valve opening / closing control unit 54 uses the signals 111 and 126 to change the ventilation valve 6. Generate a signal 127 to be activated or deactivated and command the ventilation valve 6. The information signal 111 relating to the operation of the elevator includes maintenance operation, control operation, position information of the car, and the like.

  Further, an on / off type ventilation valve operation switch 61 is provided in the vicinity of the ventilation valve 6 in order to detect that the ventilation valve 6 has actually operated as shown in FIG. When the ventilation valve 6 operates, the ventilation valve operation switch 61 is turned on, and the operation signal 128 is input from the ventilation valve operation switch 61 to the ventilation valve opening / closing control unit 54. At the same time, the operation signal 127 is transmitted from the ventilation valve 6 to the ventilation valve opening / closing control unit 54. Furthermore, these signals 127 and 128 are transmitted to the elevator control device 1 as the state signal 112 of the ventilation valve 6 via the ventilation valve opening / closing control unit 54.

  A method for ventilating the inside of the car 10 using the car ventilation control device 5 configured as described above will be described below. As the timing of ventilation in the car 10, for example, if the elapsed time after closing the car 10 with the car door 11 obtained by the door opening / closing time detection unit 51 exceeds a predetermined time. A method of setting the timing of ventilation is conceivable. However, in this method, if the car 10 is moving up and down at a high speed, the atmospheric pressure changes in the car 10, which may cause discomfort to passengers in the car 10.

Therefore, in the present invention, the ventilation timing is set according to the operating state of the car 10.
(1) When the elevator 20 is in an emergency stop and the position of the car 10 is between the floors and the car door 11 cannot be opened, the elevator control device 1 displays the operation information signal 111 as The stop signal and the position signal of the car 10 are transmitted to the ventilation valve opening / closing control unit 54. The ventilation valve opening / closing control unit 54 gives an opening command to the ventilation valve 6, ventilates the car 10, and maintains the ventilation state. If a power failure occurs when an emergency stop occurs, all control devices 1 and 5 are also stopped if there is no emergency power supply. However, since the ventilation valve 6 is normally open, it opens with a power failure, and the inside of the car 10 can be ventilated.

  (2) If the air pressure regulators 12A and 12B composed of fans or the like break down and the air in the airtight car 10 cannot be circulated, the concentration of carbon dioxide increases if there are passengers in the car 10 . Therefore, the current carbon dioxide concentration in the car 10 is detected by the carbon dioxide concentration sensor 3 to monitor whether the oxygen dioxide concentration has increased.

  On the other hand, the presence or absence of passengers in the car 10 is determined by monitoring the output of the load sensor 4. The sensor signal processing unit 52 estimates the number of passengers in the car 10 from the information of the load sensor 4 as follows. That is, the output of the load sensor 4 when there is no passenger in the car 10 is compared with the output of the current load sensor 4, and the difference is divided by the standard weight (for example, 65 kg) to estimate the number of passengers. When a signal 125 indicating that there is a passenger in the car 10 is input from the sensor signal processing unit 52 to the ventilation time calculation unit, an opening command is given to the ventilation valve 6 from the ventilation valve opening / closing control unit 54, and the inside of the car 10 is Ventilate. Thereafter, the elevator control device 1 switches to an operation that does not cause a sudden change in atmospheric pressure by reducing the driving speed of the car so as not to make passengers uncomfortable, or by performing each floor stop operation that stops at each floor.

  (3) When the elevator 20 has stopped in an emergency, but the car 10 can be moved, for example, when the stop position of the car 10 stops for some reason without entering the allowable range of the floor stop position. is there. The operation of the elevator 20 is returned, and the car 10 is moved to the destination floor designated by the landing call or the car call.

  At that time, the door opening / closing time detection unit 51 obtains an elapsed time when the car 10 becomes airtight from the time when the car door 11 detected by the door switch 2 is closed. The ventilation time calculation unit 53 determines that the carbon dioxide concentration is ambient air (the air in the hoistway 22 is the air in the hoistway 22) by the expiration of the number of passengers estimated in the same manner as described above from the obtained elapsed time and the known volume of the car 10. Calculated from the standard atmosphere). If the closed state of the car door 11 continues as it is and it is calculated that the carbon dioxide concentration exceeds the allowable value while the car 10 moves to the destination floor, the signal 122 from the carbon dioxide concentration sensor 3 is calculated. Even if the level is safe, the ventilation valve opening / closing control unit 54 gives an opening command to the ventilation valve 6 to ventilate the inside of the car 10 while it is stopped, or move the car 10 to the nearest floor And command to open the car door 11.

  (4) When the ventilation valve operation switch 61 is out of order, control is performed as follows. When raising and lowering the car 10 in the normal operation of the elevator 20, the car 10 must be airtight, so the ventilation valve opening / closing control unit 54 closes the ventilation valve 6. When the ventilating valve opening / closing control unit 54 issues a closing command to the ventilating valve 6, when the ventilating valve operation switch 61 does not operate and an abnormality is found in the operation signal 128, the elevator control device 1 Based on the signal 112 from the ventilation valve opening / closing control unit, the operation is performed with the ventilation valve 6 open. In that case, a rapid change in atmospheric pressure is prevented from occurring in the car 10 by reducing the speed of the elevator or by stopping each floor.

  By the way, the elevator airtight car ventilation control device 5 shown in the present embodiment is installed in a long-stroke or ultra-high speed elevator. Therefore, while the inside of the car 10 is airtight, as described above, the ventilation valve 6 is used as a safety measure to prevent a situation in which the concentration of carbon dioxide in the car 10 rises due to airtightness and the passenger becomes deficient. Ventilation control is provided.

  In the elevator 20 shown in the present embodiment, ventilation is possible by opening the car door 11, so that there are few operation modes in which the operation of the ventilation valve 6 is required. However, when the normally closed type ventilation valve 6 is used, if the number of times of driving is small, there is a possibility that the ventilation valve 6 may not be opened even if the ventilation valve 6 is forced to open when an abnormality occurs due to sticking of the movable part or the like. In order to avoid such a problem, a method of checking the soundness of the ventilation valve 6 by turning the ventilation valve 6 on and off every time the elevator 20 is operated can be considered. Shrink and shorten the replacement cycle.

  According to this embodiment, the normally open type ventilation valve 6 is used, and the airtight car ventilation control device 5 controls the ventilation valve 6 based on the operation signal from the elevator control device 1 and the carbon dioxide concentration in the car 10. Then, the ventilation valve 6 is actuated at the time of raising and lowering, and is normally closed. Therefore, the number of operations of the ventilation valve 6 can be suppressed, and the ventilation valve 6 is operated about once a day and avoids frequent opening and closing, so that a soundness check can be performed. In addition, the life and replacement cycle of the ventilation valve 6 can be extended.

  In this embodiment, the carbon dioxide concentration in the car 10 is estimated from the volume of the car 10, the opening / closing time of the car door 11 and the detection data of the load sensor 4, and the ventilation valve 6 is driven. Therefore, even if it becomes impossible to measure the carbon dioxide concentration level, the ventilation valve 6 can be driven to ventilate the inside of the car 10 without causing oxygen deficiency.

  Further, according to this embodiment, even if the ventilation valve 6 breaks down, no oxygen deficiency is caused. That is, when the ventilation valve 6 fails, the ventilation time calculation unit 53 calculates the ventilation timing from the signal of the ventilation valve operation switch 61 and the signal of the carbon dioxide concentration sensor 3. And the ventilation valve opening / closing control part 54 controls the elevator controller 1 to stop the car 10 at the nearest floor. As a result, the car door 11 and the landing door can be opened to ventilate the car 10.

  In the above embodiment, the airtight car ventilation control device 5 controls to open the ventilation valve 6 in accordance with the carbon dioxide concentration in the car 10. However, depending on the operation state of the elevator 20, there may be a case where the high speed and the long stroke are not achieved. In such a case, the car 10 does not necessarily need to be airtight. Therefore, the opening and closing of the ventilation valve 6 that can make the car 10 airtight is changed according to the operating condition of the elevator 20, not based on the determination based on the carbon dioxide concentration. In that case, for example, the ventilation valve 6 is operated only when the process is longer than a predetermined length or when the maximum lifting speed of the car is higher than a predetermined speed. Since a normally open type ventilation valve that is open in a normal state is used as the ventilation valve 6, the ventilation valve 6 remains open when the car 10 need not be airtight.

  As a specific example of controlling the ventilation valve 6 in accordance with the operating conditions, the elevator control device 1 can be operated when it becomes necessary to operate the car 10 in an airtight state (a condition for moving up and down the long stroke at an ultra-high speed). The ventilation valve 6 closing command 112 is given to the ventilation valve opening / closing control unit 54. At this time, if the ventilation valve operation signal 128 is not input from the ventilation valve operation switch 61 to the ventilation valve opening / closing control unit, it is determined that the car 10 is not in an airtight state, and the elevator 20 is switched to a low speed operation. Switch to an operation that does not cause sudden changes.

  Depending on the operation state of the elevator 20, passengers close to the capacity may get on, and the concentration of dioxide may increase more than expected due to the airtight state of the car 10. Even in such a case, the time until the inside of the car 10 reaches the allowable limit of the carbon dioxide concentration and the time until the car door 11 opens are always calculated. Then, when it is determined that the time that is the allowable limit of the carbon dioxide concentration is shorter than the time until the car door 11 is opened due to the car call or the landing call, the car 10 is temporarily placed on the intermediate floor. The car is stopped and the car door 11 is opened to ventilate the car 10. Or, the speed of the car 10 is reduced. At the same time, the pressure regulators 12A and 12B are temporarily stopped, the ventilation valve 6 is opened, and the inside of the car 10 is ventilated. Thereby, the lack of oxygen in the car 10 due to an unexpected increase in carbon dioxide can be prevented.

  In the above embodiment, the lack of oxygen in the car is grasped based on the carbon dioxide concentration. However, an oxygen concentration sensor may be provided directly in the car instead of the carbon dioxide concentration sensor 3. . In this case, the lack of oxygen in the car can be predicted more directly.

  According to the above embodiment, in various operation modes of the ultra-high speed / long process elevator, even if an abnormality occurs in the elevator and the equipment that ventilates the car, or the car is in an unexpected ventilation state, Since the inside of the cage can be ventilated, an oxygen deficiency can be avoided. In addition, the ventilation valve can be closed only when it is necessary to keep the car in an airtight state under various operating conditions of the elevator, which is economical without unnecessary power consumption. At the same time, a highly safe airtight car ventilator for elevators is obtained.

DESCRIPTION OF SYMBOLS 1 ... Elevator control apparatus, 2 ... Door switch, 3 ... Carbon dioxide concentration sensor, 4 ... Load sensor, 5 ... Airtight car ventilation control apparatus, 51 ... Door opening / closing time detection part, 52 ... Sensor signal processing part, 53 ... Ventilation time Calculation part 54 ... Ventilation valve opening / closing control part 6 ... Ventilation valve 61 ... Ventilation valve operation switch 10 ... Ride car 11 ... Ride car door 12A, 12B ... Barometric pressure regulator 20 ... Elevator 22 ... Hoistway , 23 ... Sheave, 24 ... Counterweight, 25 ... Main rope, 27 ... Drive motor, 28 ... Floor, 51 ... Door open / close time detector, 52 ... Sensor signal processor, 53 ... Ventilation time calculator, 54 ... Ventilation Valve opening / closing control unit, 61 ... ventilation valve operation switch, 111 ... elevator operation signal, 112 ... ventilation valve operation signal.

Claims (4)

An airtightly controllable car, airtight adjusting means for adjusting the airtightness of the car in accordance with the up and down stroke and speed of the car, and a door open / close detection switch for detecting opening and closing of the door of the car In an elevator comprising a load sensor for detecting the load of the car, a ventilation valve for making the inside of the car airtight or releasing the airtightness, and an elevator control device for controlling raising and lowering of the car,
The elevator control device transmits an operation signal of the car to the airtight adjustment means, and the airtight adjustment means includes an actual measurement value of the door open / close time detected by the door open / close detection switch and load data detected by the load sensor. Estimating the carbon dioxide gas concentration or oxygen gas concentration in the car when the car arrives at the destination floor using the volume of the car and the operation signal transmitted from the elevator control device. If the estimated gas concentration at the floor is outside the predetermined reference range, stop the car at the nearest floor and open the car door to ventilate or open the normally open vent valve to ventilate An elevator characterized by commanding at least one of the above.   The said airtight adjustment means instructs | commands that the said ventilation valve is closed, when the driving signal of the said car transmitted from the said elevator control apparatus is what drives the said car. Elevator.   A sensor for detecting carbon dioxide concentration in the car is provided in the car, and the airtight adjustment means is configured to open the ventilation valve so that the ventilation valve is opened when a detection value of the carbon dioxide concentration sensor exceeds a predetermined reference value. The elevator according to claim 1 or 2, wherein a command is given to a valve.   A sensor for detecting the oxygen concentration in the car is provided in the car, and the airtight adjustment means is configured to open the ventilation valve when the detected value of the oxygen concentration sensor is equal to or lower than a predetermined reference value. The elevator according to claim 1 or 2, characterized by:

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