JP2017065816A - Elevator and elevator control operation method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress vibration of a long load with a simple structure, without installing a dedicated appliance or a device for suppressing vibration of a long load caused by earthquake or gale in an elevator.SOLUTION: An elevator 1 of the invention is configured so that a control part 30 performs a control operation for landing a car 4 and making passengers exit to outside of the car, based on the detection result of a vibration detection part 20, and in the control operation, after making passengers exit to outside of the car 4, a hoist 7 is driven for making the car 4 operate in accelerating operation or in decelerating operation along a lifting direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an elevator and an elevator control method.

  In general, a rope type elevator is often adopted as an elevator used in a building or a condominium. In this rope type elevator, for example, in the hoistway, for example, a main rope that connects the car and the counterweight, a counter rope for adjusting the weight balance between the car and the counterweight, the car or the fishing A long object such as a governor rope used for detecting the speed of the weight is arranged. Each long object is not fixed or supported between the hoisting machine or the speed governor and the corresponding pulley. As a result, long objects may shake due to the effects of shaking of buildings due to earthquakes and strong winds.

  In recent years, building structures (hereinafter simply referred to as “buildings”) are becoming higher. However, as the height of the building increases, the length of the long object also increases, and as a result, the natural period of the building shake and the natural period of the long object swing also increase. And if the period of building shaking caused by earthquakes (especially long-period ground motion) or strong winds matches the natural period of long objects (so-called resonance occurs), the longer the natural period of long objects , Long objects tend to shake greatly. Therefore, when a long object swings greatly in the hoistway, there is a possibility that the swung long object may come into contact with or be caught by equipment or protrusions installed in the hoistway.

  Thus, conventionally, various techniques for solving the above problems have been proposed. For example, in Patent Document 1, when a building shakes due to an earthquake or strong wind, the relative displacement of a long object with respect to the displacement of the hoistway is based on a signal detected by a vibration meter installed in the building or hoistway. A technique has been proposed in which the car is urgently stopped at the nearest floor when it is estimated from the calculation information that the long object is greatly shaken.

  Conventionally, various techniques for suppressing the shake (sway) of a long object have been proposed. For example, Patent Document 2 is provided with a device that shakes the end of a long object, and the device swings the end of the long object in a phase opposite to the phase of the swinging long object. Damping techniques have been proposed. Furthermore, for example, in Patent Document 3, a dedicated device for applying tension to the main rope and the balance rope is provided, and when the sensor detects a swing of the main rope and the balance rope, the dedicated device is used to detect the main rope and the balance rope. In addition, a technique has been proposed in which tension is applied to the balance rope to suppress the swing of the main rope and the balance rope.

JP 2009-143679 A JP 2014-159328 A JP 2014-156298 A

  As described above, conventionally, various techniques for directly suppressing the shake of a long object have been proposed in an elevator. However, for example, in the techniques proposed in Patent Documents 2 and 3, etc., it is necessary to separately provide a dedicated device or device for suppressing the shake of a long object, and the installation location of the dedicated device (device) (for example, It was necessary to expand the space of hoistways and machine rooms.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a dedicated device or apparatus for suppressing the shake of a long object caused by an earthquake or a strong wind in an elevator. It is providing the technique which can suppress the shake | deflection of a long thing with a simpler structure.

  In order to solve the above-described problems, the present invention provides a car that moves up and down in a hoistway formed in a building, a main rope that is connected to the car and suspends the car in the hoistway, and drives the main rope. And an elevator equipped with a hoisting machine that raises and lowers the car in the hoistway, a swing detection unit that detects the shaking of the building, and a control unit that drives the hoisting machine and controls the raising and lowering operation of the car, and This is the control operation method. In the present invention, the control unit performs a control operation for landing the car and evacuating the passenger to the outside of the car based on the detection result of the shake detection unit. After the passenger is evacuated, the hoisting machine is driven to accelerate and decelerate the car along the up and down direction.

  In the control operation method of the elevator and the elevator of the present invention, in the control operation, after retracting the passenger to the outside of the car, by driving the hoisting machine and accelerating / decelerating the car along the ascending / descending direction, Suppresses the shake of long objects. Therefore, according to the present invention, it is possible to suppress the shake of a long object with a simpler configuration without providing a dedicated device or device for suppressing the shake of the long object as in the prior art. it can.

1 is a schematic configuration diagram of an elevator according to an embodiment of the present invention. It is a figure which shows the winding aspect of the various long objects provided in the elevator which concerns on one Embodiment of this invention. It is a flowchart which shows the procedure of the processing method of the vibration suppression function of the long thing with which the elevator which concerns on one Embodiment of this invention is provided.

  Below, the content of the elevator which concerns on one Embodiment of this invention, and the control operation method of an elevator are demonstrated concretely, referring drawings.

[Elevator overall configuration]
First, with reference to FIG.1 and FIG.2, the structure of the elevator which concerns on one Embodiment of this invention is demonstrated. FIG. 1 is a schematic configuration diagram of an elevator according to the present embodiment, and FIG. 2 is a diagram illustrating a manner of winding various long objects.

  As shown in FIGS. 1 and 2, the elevator 1 includes a car 4, a counterweight 6, a hoisting machine 7, a curling wheel 8, a pulley 10 for a balancing rope, a speed governor 11, Two tension wheels 13 and 17, two connecting members 14 and 18, and a counterweight governor 15 for counterweight are provided. The elevator 1 includes various long objects such as a main rope 5, a balancing rope 9, a governor rope 12, and a governor rope 16 for a counterweight. Further, the elevator 1 includes a shake detection unit 20 and a control unit 30.

  The car 4 and the counterweight 6 are arranged in the hoistway 2 formed in the building and move up and down in the hoistway 2. The balancing rope pulley 10 and the two tension wheels 13 and 17 are arranged in the vicinity of the bottom in the hoistway 2. The hoisting machine 7, the warping wheel 8, the speed governor 11, the counterweight speed governor 15, the shake detection unit 20, and the control unit 30 are installed in a machine room 2 a provided in the upper part of the hoistway 2. Is done. The curling wheel 8 is disposed in the vicinity of the hoisting machine 7.

  Although not shown in detail in FIGS. 1 and 2, in the elevator 1 of the present embodiment, the control unit 30 is electrically connected to each unit controlled thereby and each unit for detecting the state of the elevator 1. Has been. For example, the control unit 30 is electrically connected to the hoisting machine 7, the shake detection unit 20, and the like (see the broken line in FIG. 1).

[Configuration of each part]
The car 4 has a hollow, substantially rectangular parallelepiped shape, on which passengers and luggage are placed. A door (not shown) is provided on the side surface of the car 4. The door is opened and closed mainly by a passenger operating an operation panel (not shown) provided in the car 4 during normal operation, and opened and closed under the control of the control unit 30 during control operation. Further, a slider 4 a is provided on the outer side surface of the car 4, and the slider 4 a is slidably supported by a guide rail 3 provided in the hoistway 2. Therefore, the car 4 moves up and down in the hoistway 2 along the guide rail 3.

  The main rope 5 is composed of a plurality of ropes. As shown in FIGS. 1 and 2, the main rope 5 is wound around a hoisting machine 7 and a warping wheel 8 installed in the machine room 2a. One end of the main rope 5 is connected to the upper part of the car 4, and the other end is connected to the upper part of the counterweight 6. That is, the car 4 and the counterweight 6 are suspended by the main rope 5 via the hoisting machine 7 and the curling wheel 8 in a slidable manner.

  In this embodiment, it is assumed that the weight of the counterweight 6 is set to be approximately the same as the weight of the car 4 when not loaded, plus half the weight of the car 4 that can be loaded. . Therefore, when an object or person is loaded in the car 4 with half the maximum load weight, the tension applied to the main rope 5 on the car 4 side and the tension applied to the main rope 5 on the counterweight 6 side The ratio is 1. By adopting such a configuration, the hoisting machine 7 can be used when there is no load in the car 4 when no objects or people are loaded, or when there is a maximum load of objects or people in the car 4. Although the output torque is maximized, the output necessary for the operation of the hoisting machine 7 can be minimized. In addition, the weight of the counterweight 6 is not limited to the example of this embodiment, It can set suitably according to the specification of the elevator 1, etc.

  The hoisting machine 7 raises and lowers the car 4 and the counterweight 6 via the main rope 5. Specifically, the hoisting machine 7 transmits the output torque to the car 4 and the counterweight 6 via the main rope 5, and the car 4 and the counterweight 6 are moved vertically in the hoistway 2 ( It is moved up and down in the direction of arrow A in FIG.

  The balancing rope 9 is composed of a plurality of ropes. As shown in FIG. 2, the balancing rope 9 is wound around a balancing rope pulley 10 disposed near the bottom of the hoistway 2. One end of the balancing rope 9 is connected to the lower part of the car 4, and the other end is connected to the lower part of the counterweight 6.

  The balance rope 9 is a rope provided to balance the weight with the main rope 5. Specific effects obtained by providing the balancing rope 9 are as follows.

  When the elevator car 4 and the counterweight 6 are moved up and down during the operation of the elevator 1, the length of the main rope 5 on the car 4 side when the hoisting machine 7 is used as a fulcrum changes depending on the position of the car 4. . In this case, the difference between the tension applied to the main rope 5 on the car 4 side by its own weight and the tension applied to the main rope 5 on the counterweight 6 side due to its own weight is increased. Insufficient friction transmission from the machine 7 to the main rope 5 may occur. In order to eliminate such a situation, in the present embodiment, a balancing rope 9 is provided that is suspended below the car 4 and the counterweight 6. Due to the weight of the balancing rope 9, the difference between the tension applied by the weight of the main rope 5 on the car 4 side and the tension applied by the weight of the main rope 5 on the counterweight 6 side can be reduced. In the present embodiment, the weight of the balancing rope 9 can be set to a weight that is equal to or substantially equal to the weight of the main rope 5, for example.

  The governor 11 detects when the moving speed of the car 4 exceeds a specified value, and urgently stops the car 4.

  The governor rope 12 is configured by a rope in which both ends in the extending direction are connected to each other, that is, an endless rope. As shown in FIGS. 1 and 2, the governor rope 12 is wound around a governor 11 provided in the machine room 2 a and a tension wheel 13 disposed near the bottom in the hoistway 2. . A part of the governor rope 12 is connected to the car 4 via the connection member 14. Thereby, the governor rope 12 circulates between the governor 11 and the tension wheel 13 in accordance with the raising / lowering operation of the car 4.

  The counterweight governor 15 detects when the moving speed of the counterweight 6 exceeds a specified value, and urgently stops the car 4.

  The counterweight governor rope 16 for the counterweight is composed of a rope in which both ends in the extending direction are connected to each other, that is, an endless rope. As shown in FIG. 2, the balance weight governor rope 16 includes a balance weight governor 15 provided in the machine room 2 a and a tension wheel 17 disposed in the vicinity of the bottom in the hoistway 2. It is wrapped around A part of the counterweight governor rope 16 for the counterweight is connected to the counterweight 6 via the connecting member 18. Thereby, the balance weight governor rope 16 circulates between the balance weight governor 15 and the tension wheel 17 in accordance with the lifting and lowering operation of the balance weight 6.

  The shake detection unit 20 detects a building shake (particularly a long-period building shake) generated in a building due to an impact such as an earthquake (particularly long-period ground motion) or strong wind. Then, the shake detection unit 20 outputs information regarding the detected building shake to the control unit 30. In addition, the building shake detection apparatus which comprises the shake detection part 20 can use arbitrary apparatuses, if it is an apparatus which can detect a building shake. For example, a device that detects the acceleration of building shaking as information related to building shaking can be used.

  In the present embodiment, the example in which the shake detection unit 20 is disposed in the machine room 2a has been described. However, the present invention is not limited to this. The arrangement position of the shake detection unit 20 can be appropriately changed according to the configuration conditions such as the type (detection principle) of the building shake detection device employed and the presence or absence of the machine room 2a.

  The control unit 30 includes, for example, a circuit (microcomputer) in which a CPU (Central Processing Unit), a memory, and the like are integrated on an LSI (Large-scale Integration) chip, and controls the overall operation of the elevator 1. For example, the control unit 30 controls the operation of the normal operation in which passengers and luggage are transported by the car 4, and also controls the operation of the control operation performed in the event of a disaster such as an earthquake or a fire. In addition, the control unit 30 also performs control to switch between normal operation and control operation based on information indicating an emergency, such as information on building shake detected by the shake detection unit 20, for example. As will be described later, the elevator 1 of the present embodiment has a function of suppressing the shake of a long object during control operation (hereinafter, referred to as a “long object shake suppressing function”). The control unit 30 also performs operation control of the shake suppression function.

[Long vibration control function during elevator control operation]
Next, in the elevator 1 of this embodiment, the content of the long-body shake suppression function executed during the control operation will be described.

(1) Outline of long object shake suppression function First, an operation outline of the long object shake suppression function executed by the elevator 1 of the present embodiment will be described. In the present embodiment, when the control unit 30 detects a building shake (a shake of a long object) caused by an earthquake or a strong wind based on the information about the building shake detected by the shake detection unit 20, the operation is controlled. Switch to driving. When the control operation is started, first, the control unit 30 moves the car 4 to the nearest floor and stops (landing) it, opens the door (door) of the car 4 and takes passengers or the like. Retract to the outside of the car 4. Subsequently, after a passenger etc. evacuate to the exterior of the car 4, the control part 30 closes the door of the car 4, and operates the shake suppression function of a long thing.

  Next, when the operation of the long object shake suppression function is started, the control unit 30 continuously moves the car 4 in the up-and-down direction (vertical direction) in the hoistway 2 during the period when the building shake is detected. Accelerate and decelerate along The acceleration / deceleration operation of the car 4 is executed when the control unit 30 drives and controls the hoisting machine 7.

  By the acceleration / deceleration control of the car 4 by the control unit 30, the tension applied to the long object can be continuously changed, and the natural period of the long object can be continuously changed. As a result, the continuous change in the tension can suppress the vibration (resonance) of the long object and prevent the vibration (resonance) of the long object from continuing for a long time.

  Next, when the shaking of the building is no longer detected, the control unit 30 ends the operation of the long object shake suppression function and automatically diagnoses whether normal operation can be resumed. When it is determined that the normal operation can be resumed by this automatic diagnosis, the control unit 30 resumes the normal operation, and when it is determined that the normal operation cannot be resumed, The control unit 30 stops the operation of the elevator 1.

(2) Processing Method for Long Object Shake Suppression Function Next, an example of a processing method for a long object shake suppression function performed during control operation in the elevator 1 of the present embodiment will be described with reference to FIG. To do. FIG. 3 is a flowchart illustrating a procedure of a processing example of the long object shake suppression function executed in the elevator 1 of the present embodiment.

  First, during normal operation, the control unit 30 determines whether or not a shake of a long object (building shake) due to an earthquake, strong wind, or the like has been detected based on information about the building shake input from the shake detection unit 20. Is determined (step S1). This process may be performed at any time during normal operation or periodically. Further, in this process, for example, the control unit 30 estimates (predicts) the amount of shake of each long object based on information on the building shake, and compares the estimated shake amount with a predetermined threshold value. Thus, it may be determined whether or not a long object shake due to an earthquake or a strong wind has occurred. Further, for example, in this process, the control unit 30 compares the information about the building shake input from the shake detection unit 20 with the threshold value of the information, and shakes a long object caused by an earthquake or a strong wind (building) It may be determined whether or not (sway) has been detected.

  In step S1, when the control unit 30 determines that a long-body vibration (building shake) due to an earthquake, strong wind, or the like has not been detected (when step S1 is NO), the control unit 30 performs normal operation. (Step S2). On the other hand, when the control unit 30 determines in step S1 that a swing of a long object (building shake) due to an earthquake, strong wind, or the like has been detected (when step S1 is YES), the control unit 30 is normal. The operation is switched to the control operation (step S3).

  After the processing of step S3, the control unit 30 drives the hoisting machine 7, moves the car 4 to the nearest floor, and stops (lands) the car 4 on the nearest floor (step S4). Next, the control unit 30 opens the door of the car 4 (step S5). This process makes it possible to evacuate passengers and the like in the car 4 to the outside. Next, after a predetermined time has elapsed since the door of the car 4 is opened, or based on the detection result of a sensor (not shown) provided in the car 4, it is controlled that there are no passengers or the like in the car 4. If the unit 30 determines, the control unit 30 closes the door of the car 4 (step S6).

  Next, the control unit 30 determines whether or not the nearest floor where the car 4 is stopped in step S4 is a non-resonant floor (step S7).

  “Non-resonant floor” means that the natural period of swinging long objects such as the main rope 5 and the balancing rope 9 when the car 4 is stopped on that floor is different from the natural period of building shaking. This is a floor that is not easily affected by the shaking of the building (a floor where long objects do not resonate with the shaking of the building). Therefore, if the car 4 is stopped on the non-resonant floor, the swing of each long object existing in the hoistway 2 does not grow greatly.

  In the present embodiment, the position information regarding the non-resonant floor is obtained at the design stage of the elevator 1. The position information of the non-resonant floor is obtained based on the information on the natural period of the building shake and the natural period of each long object. The information on each natural period is obtained at the design stage. It is calculated | required previously based on the installation structure (specification) of 1 etc. Therefore, in the present embodiment, the control unit 30 performs the determination process in step S7 based on the information on the non-resonant floor that is obtained in the design stage of the elevator 1 and the information on the current stop position of the car 4. .

  The information on the current stop position of the car 4 can be acquired based on information such as the amount of the main rope 5 wound up by the hoisting machine 7, for example. In the present embodiment, a position detection device for detecting the position of the car 4 is separately provided, and the control unit 30 is based on the position information of the car 4 detected by the position detection device. You may grasp the current stop position.

  In addition, since the natural period of the swing of the long object changes depending on the tension or the length applied to the long object, a plurality of types of ropes (long objects) having different lengths and their own weights as in the present embodiment. In the elevator 1 having a rope (long object), the natural periods of the swing of each rope (long object) are also different from each other. For example, for the main rope 5, the length from the hoisting machine 7 serving as a fulcrum to the car 4 changes according to the position of the car 4, and the tension applied to the main rope 5 on the car 4 side. Also changes. Furthermore, the tension applied to the main rope 5 on the side of the car 4 changes according to the weight of the car 4. Therefore, in the present embodiment, the natural period of the main rope 5 swing corresponding to the position of the car 4 and the weight of the car 4 is also obtained in advance at the design stage.

  Therefore, in the present embodiment, the example in which the determination process of step S7 is performed using the information of the non-resonant floor that is obtained in advance at the design stage when the building shake is detected is described, but the present invention is not limited to this. The position of the non-resonant floor may be estimated based on the natural period of the swing of each rope (long object) obtained in advance, and the determination process in step S7 may be performed.

  Here, it returns to the process of step S7 again, and when the control part 30 discriminate | determines in step S7 that the nearest floor which stopped the cage | basket | car 4 at step S4 is a non-resonance floor (step S7 is YES determination) In this case, the control unit 30 continues the stop operation of the car 4 at the nearest floor (stop floor of the car 4) (step S8). That is, when the nearest floor where the car 4 is stopped in step S4 is a non-resonant floor, the control unit 30 performs control such that the car 4 stands by on the non-resonant floor until the shaking of the building is settled. And after that, the control part 30 performs the process of below-mentioned step S10.

  On the other hand, if the control unit 30 determines in step S7 that the nearest floor where the car 4 was stopped in step S4 is not a non-resonant floor (if NO in step S7), the control unit 30 determines that the car 4 The control for accelerating and decelerating along the ascending / descending direction (vertical direction) is started or continued (step S9). That is, the control unit 30 performs the process of starting or continuing the operation of the long object shake suppression function by this process. In addition, when step S9 is performed after the process of step S6, the control part 30 performs control which starts the action | operation of the shake suppression function of a long thing in the process of step S9, and after the process of step S10 mentioned later When step S9 is performed, the control unit 30 performs control to continue the operation of the long object shake suppression function in the process of step S9.

  In the present embodiment, when the operation of the long object shake suppression function is started, the following acceleration / deceleration operation is performed on the car 4. First, the control unit 30 causes the car 4 to perform operations of acceleration, deceleration, and stop (direction change) in one of the upward direction and the downward direction. Next, the control unit 30 causes the car 4 to perform acceleration, deceleration, and stop (direction change) operations in the other direction, the upward direction and the downward direction. After that, the control unit 30 continuously (continuously) repeats this series of acceleration / deceleration operations during a period in which the swing of a long object (building shake) is detected.

  In the acceleration / deceleration operation for the car 4 according to the present embodiment described above, the acceleration and the movement distance (movement time) of the car 4 during the acceleration period and the deceleration period are, for example, long objects detected by the shake detection unit 20. Can be set as appropriate based on information such as the magnitude of the swing (building shake), the stop position of the car 4 (the length of the main rope 5 on the car 4 side), the weight of the car 4, and the like. In the present embodiment, the acceleration and movement distance (movement time) of the car 4 in the acceleration operation and the deceleration operation of the car 4 in the upward direction, that is, the acceleration / deceleration mode of the car 4 in the upward direction is as follows. It may be the same as that of the direction or may be different. Furthermore, the acceleration / deceleration mode (acceleration and moving distance (moving time)) of the car 4 may be constant during the period in which the swing of the long object (building shake) is detected. For example, the long object You may change at any time according to the magnitude | size of shaking (building shaking).

  After the processing of step S8 or step S9, the control unit 30 determines whether or not the building shake (long object shake) has converged based on the information about the building shake input from the shake detection unit 20 (step S10). In step S10, when the control unit 30 determines that the building shake (the swing of the long object) has not converged (when step S10 is NO), the control unit 30 returns the process to step S7, The processes after S7 are repeated.

  On the other hand, when the control unit 30 determines in step S10 that the shaking of the building (swing of a long object) has converged (if step S10 is YES), the control unit 30 accelerates / decelerates the car 4. The operation control is stopped (step S11). That is, the control unit 30 stops the operation of the long object shake suppression function by this processing. When the nearest floor where the car 4 is stopped in step S4 is a non-resonant floor and the process proceeds to the process of step S11 via the stop continuation process of the car 4 of step S8, the control unit 30 The operation in step S11 is not performed.

  Next, the control unit 30 performs an automatic diagnosis process (step S12). In this automatic diagnosis process, various confirmation processes for diagnosing whether or not the normal operation of the elevator 1 can be resumed are performed to ensure safety. Specifically, the control unit 30 performs, for example, a confirmation process as to whether or not a long object is caught on a device or protrusion in the hoistway 2, a confirmation process as to whether or not an abnormal sound is generated in the car 4, Processing for confirming the presence or absence of abnormality of the counterweight 6 is performed.

  Next, the control unit 30 determines whether or not the normal operation of the elevator 1 can be resumed based on the result of the automatic diagnosis process performed in step S12 (step S13). In step S13, when the control unit 30 determines that the normal operation can be resumed (when step S13 is YES), the control unit 30 starts the automatic return operation (step S14). By this process, the normal operation of the elevator 1 is automatically restored.

  On the other hand, when the control unit 30 determines in step S13 that the normal operation cannot be resumed (when step S13 is NO), the control unit 30 stops the operation of the elevator 1 (step S15). . When the operation of the elevator 1 is stopped by the process of step S15, the maintenance operation by the maintenance staff, the safety confirmation work, the recovery work, and the like are performed on the elevator 1, and then the normal operation of the elevator 1 is resumed.

  In this embodiment, at the time of building shaking detection, the control operation of the elevator 1 is performed as described above.

  As described above, in the present embodiment, when a shake of a long object (building shake) caused by an earthquake or strong wind is detected and the shake suppression function of the long object is activated, the control unit 30 is hoisted. The machine 7 is controlled to accelerate or decelerate the car 4 in the vertical direction. Then, during the period in which the swing of the long object (building shake) is detected, the acceleration / deceleration operation (long object swing suppression function) of the car 4 is continuously executed. As a result, the tension applied to the main rope 5 connected to the car 4 changes without interruption during the period in which the swing of the long object (building shake) is detected, and each long object (main rope 5, balance rope). 9. The natural period of the governor rope 12 and the counterweight governor rope 16) is constantly changing.

  Therefore, in this embodiment, when a shake of a long object (building shake) due to an earthquake or a strong wind is detected, the long object shake suppression function described above is activated, so that each long object is activated. It is possible to forcibly suppress shaking of objects. That is, in the present embodiment, it is possible to suppress the shake of each long object with a simpler configuration without newly providing a dedicated device or apparatus for suppressing the shake of the long object as in the past. it can.

  Further, in the long object shake suppression function of the present embodiment, during the period in which the long object shake (building shake) is detected, the operation of acceleration, deceleration and stop of the car 4 is continuously repeated to the main rope 5. Since the tension (natural period of each long object) is constantly changed to suppress the vibration of each long object, the elevator 1 can be restored earlier.

  Further, in the control operation of the present embodiment, as described in the flowchart shown in FIG. 3, when the nearest floor where the car 4 is stopped is not a non-resonant floor, the control unit 30 adds the car 4. When the nearest floor where the car 4 is stopped and the car 4 is stopped is a non-resonant floor, the control unit 30 keeps the car 4 stopped at the nearest floor (see step S8). When such a process is performed, in the control operation at the time of building shake detection, it is possible to apply a suitable method for suppressing the shake of a long object according to the floor (position) on which the car 4 is landed. Efficient long object shake suppression processing can be realized. The present invention is not limited to this, and the control unit 30 may perform the acceleration / deceleration operation of the car 4 even when the nearest floor where the car 4 is stopped is a non-resonant floor.

  Further, according to the above configuration of the present embodiment, the following effects can also be obtained. Conventionally, as a countermeasure when a building shake is detected, the passenger is moved down to the non-resonant floor after the passenger has been lowered before the swing of the long object becomes large, and the swing of the long object is increased. A technique for avoiding this has also been proposed. However, with this conventional method, when the distance until the car is moved to the non-resonant floor is long and the movement time becomes long, resonance occurs until the car moves to the non-resonant floor, There is also a risk that runout will increase.

  In addition, when there are a plurality of types of long objects in the elevator, the natural periods of the respective long objects are different. Therefore, in the elevator hoistway, all the long objects are in non-resonant positions (or all Since the range of the position where the shake of the long object is reduced on average is very narrow, it may take time to determine the non-resonant floor. Therefore, in the method of moving the car to the non-resonant floor as described above, after performing processing such as predicting the swing of each long object and determining the non-resonant floor, the passenger is taken down from the car, and the car is moved. When the vehicle is moved to the non-resonant floor, there is a shortage of time, and there is a risk that the swing of the long object will increase before the car moves to the non-resonant floor.

  On the other hand, in the long object shake suppression function of the present embodiment described above, after the passenger is lowered from the car 4 on the nearest floor, the operation of moving the car 4 to the non-resonant floor is not performed. The car 4 is accelerated or decelerated in the vertical direction to suppress the swing of each long object. In addition, in the long object shake suppression function of the present embodiment described above, it is not necessary to perform a non-resonant floor determination process as in the prior art. Therefore, according to the present embodiment, it is possible to solve the problems that may occur in the conventional method of moving the car described above to a non-resonant floor.

[Variations]
The elevator and the elevator control operation method according to the present invention are not limited to the example of the above-described embodiment, and include, for example, the following various modifications.

  In the above embodiment, the acceleration / deceleration operation (a series of operations of acceleration, deceleration, and stop (direction change)) in the vertical direction (lifting direction) of the car 4 is performed while the vibration suppression function of the long object is operating. Although an example in which the tension applied to each long object is continuously changed has been described without interruption, the present invention is not limited to this. For example, an operation of moving the car 4 at a constant speed between the acceleration operation and the deceleration operation of the car 4 may be performed, or the stop operation may be continued for a predetermined period.

  Moreover, in the said embodiment, based on the information regarding the building shake detected by the shake detection part 20 (For example, the amount of shake of each long thing is estimated by calculation etc. from this information), the shake of a long thing Although the example (refer step S1 in the flowchart shown in FIG. 3) which detects this was demonstrated, this invention is not limited to this. For example, a shake detector that can directly detect the shake of a long object may be provided separately. In addition, the shake detector of a long object can be configured using, for example, an optical sensor.

  Further, in the control operation method of the above embodiment, in the process of step S7 in the flowchart shown in FIG. 3, it is determined whether or not the nearest floor where the car 4 is stopped (emergency stop) in step S4 is a non-resonant floor. Although the example which discriminate | determines and discriminate | determines whether to operate the shake suppression function of a long object based on this discrimination | determination result was demonstrated, this invention is not limited to this. For example, in the process of step S7, the control unit 30 performs a determination process that compares the shake of the long object when the car 4 is stopped on the nearest floor with a predetermined threshold, and the shake of the long object is detected. When the predetermined threshold value is exceeded, the long object shake suppression function may be activated. At this time, the shake of the long object when the car 4 is stopped at the nearest floor may be calculated based on the detection result of the shake detection unit 20, for example. A shake detector may be provided to directly detect the shake of a long object. In the case of such a configuration, the long object of the present invention even in an elevator for which information on the non-resonant floor is not obtained in advance or an elevator that does not have a processing function for calculating the position of the non-resonant floor during control operation Can be applied.

  The elevator and the elevator control operation method according to the embodiment of the present invention and various modifications thereof have been described above, but the present invention is not limited to these, and the present invention described in the scope of the claims is not limited thereto. Various other application examples and modifications can be taken without departing from the gist.

  For example, the above-described embodiment is a detailed and specific description of the configuration of the apparatus (elevator) in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one having all the configurations described. Absent.

  In addition, each of the configurations, functions, processing units, and the like related to the above-described control may be realized by hardware by designing a part or all of them with, for example, an integrated circuit. In addition, each configuration, function, and the like related to the above-described control may be realized by software by the processor interpreting and executing a program that realizes each function. Information (data) such as programs, tables, and files for realizing each function is stored in a memory, a recording device such as a hard disk or SSD (Solid State Drive), or a recording medium such as an IC card, SD card, or DVD. can do.

  DESCRIPTION OF SYMBOLS 1 ... Elevator, 2 ... Hoistway, 2a ... Machine room, 4 ... Riding car, 5 ... Main rope, 6 ... Counterweight, 7 ... Hoisting machine, 8 ... Warping car, 9 ... Counterbalance rope, 10 ... Fishing Pulleys for combined rope, 11 ... governor, 12 ... governor rope, 13 ... tensioner, 14 ... connecting member, 15 ... governor for counterweight, 16 ... governor rope for counterweight, 17 ... Tension wheel, 18 ... Connecting member, 20 ... Swing detection unit, 30 ... Control unit

Claims (4)

A car that goes up and down in the hoistway formed in the building,
A main rope connected to the car and suspending the car in the hoistway;
A hoisting machine that raises and lowers the car in the hoistway by driving the main rope;
A shaking detector for detecting shaking of the building;
In an elevator comprising a control unit that drives the hoisting machine and controls the lifting operation of the car,
The control unit performs a control operation of landing the car and evacuating a passenger to the outside of the car based on the detection result of the shake detection unit, and in the control operation, the control part is outside the car. After evacuating a passenger, the hoisting machine is driven to accelerate and decelerate the car along the ascending / descending direction. The control unit continuously performs control for accelerating / decelerating the car along an ascending / descending direction while the building detector detects the shaking of the building. The elevator described in 1. When the position where the car is landed is a non-resonant floor, the control unit, after retracting a passenger outside the car, without performing the acceleration / deceleration operation on the car, The elevator according to claim 1 or 2, wherein the car is kept stopped at that position. A car that moves up and down in a hoistway formed in a building, a main rope that is connected to the car and suspends the car in the hoistway, and drives the main rope to drive the car Elevator control operation method comprising a hoisting machine that moves up and down in a hoistway, a sway detector that detects swaying of the building, and a controller that controls the elevating operation of the car by driving the hoisting machine In
The control unit performs a control operation of landing the car and evacuating a passenger to the outside of the car based on the detection result of the shake detection unit, and in the control operation, the control part is outside the car. An elevator control operation method comprising driving a hoisting machine and accelerating / decelerating the car along an ascending / descending direction after evacuating a passenger.

Images