The present application is based on PCT filing PCT/JP2018/001039, filed Jan. 16, 2018 which claims priority to JP 2017-027831, filed Feb. 17, 2017, the entire contents of each are incorporated herein by reference.
The present invention relates to an elevator device including a brake device provided to a car.
It is known that a traction type elevator device supports and drives a car with use of a main rope, and hence the car shakes due to stretching and shrinking of the main rope or lateral oscillation occurs due to slacking of the main rope itself. In particular, in a traction type elevator device having a large vertical travel distance, which is installed in, for example, a high-rise building, the stretching and shrinking or the slacking is liable to occur because of the use of the main rope having a long length.
Accordingly, the above-mentioned shaking or oscillation is liable to occur.
In the related art, brake devices are provided to the car and a counterweight to prevent jumping of the car or the counterweight and slacking of the main rope resulting therefrom, which may otherwise be caused by an operation of a brake for a hoisting machine or a buffer especially in case of emergency stop. With the configuration described above, collision of the car or the counterweight against a device in a hoistway due to the slacking of the main rope or generation of a large impact force at the time when the main rope becomes taut again after slacking is prevented (see, for example, Patent Literature 1).
[PTL 1] JP 2012-515126 A1 (paragraph 0021)
In the elevator device described above, the shaking caused by the stretching and shrinking of the main rope cannot be eliminated under states other than the emergency stop condition. As a result, there arise problems in that the shaking of the car that is currently running may increase to impair ride comfort and that the main rope may resonate with side-to-side shaking of a construction, which is caused by an earthquake or a strong wind, to swing and collide against the device in the hoistway.
Further, in the elevator device having a large vertical travel distance, which is installed in, for example, the high-rise building, the main rope is liable to oscillate. In addition, the long main rope is arranged between the car and the hoisting machine. Thus, there is a problem in that it is difficult to suppress the shaking of the car through the control of the drive of the hoisting machine alone.
The present invention has been made to solve the problems described above, and has an object to provide an elevator device capable of eliminating shaking of a car regardless of a state of a main rope.
In order to achieve the above-mentioned object, an elevator device according to one embodiment of the present invention includes a car, a counterweight, a main rope configured to support the car and the counterweight, a hoisting machine to be driven with the main rope wound therearound, car rails configured to guide the car, a car brake device configured to apply a load to the car rails to control raising and lowering of the car, a hoisting-machine controller configured to control the hoisting machine, a car brake controller configured to control the car brake device, and a vibration detection device configured to detect vibration of the car. When the vibration of the car is detected based on an output signal from the vibration detection device under a running state in which the hoisting-machine controller controls the drive of the hoisting machine, the car brake controller controls the car brake device to generate a braking force until the vibration becomes smaller than a set value.
The elevator device according to one embodiment of the present invention is configured such that, when the vibration of the car is detected based on the output signal from the vibration detection device under the running state, the car brake device is controlled to generate the braking force until the vibration becomes smaller than the set value. Accordingly, the effect of reducing the shaking of the car, which is caused by the stretching and shrinking of the main rope, to improve ride comfort is obtained.
Now, an elevator device according to each of various embodiments of the present invention is described in detail with reference to the accompanying drawings.
The car 1 includes a car brake device 8 configured to apply a load to the car rails 6 to brake the car 1. The car brake device 8 holds the car rails 6 to prevent stretching and shrinking of the main rope 5 so that the car 1 is not vertically positionally shifted when a user boards or exits the car 1, or is operated in case of emergency such as occurrence of a failure of a device to decelerate and stop the car 1. Besides, the car brake device 8 can be actuated while the car 1 is running. A period in which the car 1 runs includes a period in which the car 1 accelerates, a period in which the car 1 runs at a constant velocity, and a period in which the car 1 decelerates.
Further, the elevator device includes an elevator controller 9 configured to control an operation of the elevator device itself. The elevator controller 9 includes at least a hoisting-machine controller 9a and a car brake controller 9b. The hoisting-machine controller 9a is configured to control drive of the hoisting machine 3. The car brake controller 9b is configured to control the car brake device. In addition, the elevator device described above includes a tension detection device 10. The tension detection device 10 is configured to detect a tension of the main rope 5. More specifically, as the tension detection device 10, there are exemplified a break detection device configured to detect break of the main rope 5 based on the load and a weighing device configured to detect a weight in the car based on a change in load.
With the configuration described above, the car brake controller 9b is configured to control the car brake device 8 to generate the braking force based on an output signal from the tension detection device 10 under a state in which the hoisting-machine controller 9a controls the drive of the hoisting machine 3. Thus, when the tension detection device 10 detects vibration associated with car shaking to control the car brake device 8 to generate the braking force while the car 1 is running, the shaking of the car 1, which is caused by the stretching and shrinking of the main rope 5, can be suppressed. Specifically, the tension detecting device 10 functions as a vibration detection device configured to detect the vibration associated with the car shaking.
In the stop mode in
Meanwhile, in the running mode in
After that, it is determined whether or not the vibration of the main rope tension has become smaller than a set value (STEP 3a). When the vibration of the main rope tension has become smaller than the set value, the car brake device 8 is released. Then, the processing returns to STEP 1a where the generation of the vibration of the main rope tension is checked (STEP 1a). A magnitude of the braking force of the car brake device 8 may be constant or may be periodically changed as described later. In general, during the period in which the car 1 is accelerated or the period in which the car 1 is controlled to run at a constant velocity, the car brake device 8 is not actuated to perform braking. However, when the vibration of the car 1 is detected especially in any one of the periods described above, the braking force of the car brake device 8 is generated to thereby obtain a vibration suppression effect, which has not been obtained in the related art. The vibration suppression effect is obtained because the tension of the main rope 5 can be directly controlled at both ends of the main rope 5.
The braking force in
In the stop mode in
After the stop mode is switched to the running mode in
When it is determined that the vibration of the main rope tension has occurred, the car brake device 8 is actuated (STEP 2a). Then, it is determined whether or not the vibration of the main rope tension has become smaller than a set value, specifically, whether the vibration of the main rope tension, which is equal to or larger than the set value, has not occurred (STEP 3a).
More specifically, it is determined based on the stored main rope tension value T (STEP 2b) whether the tension having a magnitude equal to or larger than Δt2, which is predetermined as an allowable range of tension amplitude, has been absent for a given period of time. When a result of determination is YES, it is determined that the vibration of the main rope tension has converged, and the car brake device 8 is released (STEP 4a). In this case, the given period of time can be suitably determined. However, it is considered that the given period of time is determined based on, for example, one period w of the vibration of the main rope tension as a reference. The one period w can be set to, as illustrated in
Meanwhile, in order to efficiently suppress the vibration of the main rope tension, it is preferred to generate the braking force of the car brake device 8 in a direction of suppressing the stretching and shrinking of the vibration of the main rope. Thus, it is preferred that the braking force be exerted in a direction in which the car is lowered at timing of decreasing the tension or be exerted in a direction in which the car 1 is raised at timing of increasing the tension. When the car brake device 8 is operated at the above-mentioned timing, with the same period as the vibration of the main rope tension, the braking force is applied in an upward direction for the car 1 at timing at which the main rope tension becomes weak. Specifically, as illustrated in
Further, as illustrated in
Further, as illustrated in
In the elevator device in this embodiment, the vibration of the main rope tension of the main rope 5 is detected by the tension detection device 10 arranged on top of an outer side of the car 1. However, a tension detection device arranged at another position may be used as long as the main rope tension can be checked.
As described above, in the elevator device according to the first embodiment of the present invention, the shaking of the car that is currently running is controlled by the car brake controller. With the control described above, the effect of reducing the shaking of the car due to the stretching and shrinking of the main rope to improve the ride comfort is obtained. In particular, the shaking of the car is sometimes increased at an acceleration at a switching point between a section in which the car is accelerated or decelerated and a section in which the car is operated at a constantly maintained velocity. The control may be performed so as to directly detect the shaking with high sensitivity to suppress the shaking.
Hitherto, when the drive control is performed so as to achieve the acceleration or the constant velocity, the braking force of the brake is not generated on the car side. Thus, it is difficult to suppress the shaking due to the stretching and shrinking of the main rope on the hoisting machine side. According to this embodiment, the tension can be directly controlled at both ends of the main rope. Accordingly, the shaking can easily be suppressed.
In this embodiment, the vibration of the main rope tension cannot be directly detected. However, under a state in which a fluctuation in tension of the main rope 5 occurs to shake the car 1, a load value output from the load detection device 11 provided in the car 1 also oscillates. The car brake device 8 is controlled to generate a braking force corresponding to the load value. With the thus generated braking force, the shaking can be suppressed.
In particular, for a fluctuation in main rope tension, which is caused by the user who is present in the car 1 and shakes the car 1, an external force applied from inside of the car 1 can be directly detected at a position of the car 1. Thus, the vibration of the car 1 can be directly suppressed in a direction in which the external force is cancelled by the car brake device 8. Accordingly, the shaking of the car 1 can be efficiently reduced with high accuracy.
Also in this embodiment, the load detection device 11 functions as the vibration detection device configured to detect the vibration of the car 1. For the control of the car brake device 8, which is performed so as to suppress the detected vibration, the same method as that of the first embodiment may be used.
As described above, in the elevator device according to the second embodiment of the present invention, the car brake controller controls the car brake device so as to efficiently cancel the shaking of the car that is currently running, especially, the external force applied from inside of the car to generate the braking force. With the braking force, the effect of reducing the shaking of the car due to the stretching and shrinking of the main rope to improve the ride comfort is obtained.
In a case in which the elevator controller 9 detects the shaking of the construction, which is equal to or larger than a set value, there is a risk in that, when the construction shakes side-to-side due to an earthquake or a strong wind, the main rope 5 may swing due to the resonance to collide against and damage a device in a hoistway. Thus, it is common to temporarily stop the service and restart the service after an inspection.
Meanwhile, the elevator device according to the present invention includes the car brake controller 9b. Thus, under the running state in which the hoisting-machine controller 9a controls the drive of the hoisting machine 3, the braking force of the car brake device 8 can be generated. In particular, the drive of the hoisting machine 3 can be controlled in accordance with the shaking of the construction, which is caused by the earthquake or the strong wind. Accordingly, through the control of the drive of the hoisting machine 3 so as to suppress the vibration of the main rope 5 due to the earthquake or the strong wind, the oscillation of the main rope 5 is suppressed. In this manner, the swing of the main rope 5, which may be caused by the resonance, can be prevented so as to avoid the collision against the device in the hoistway.
In the suspension mode in
Next, a specific control method of suppressing the shaking of the car 1, specifically, the oscillation of the main rope 5 in this embodiment is described. Lateral oscillation of the main rope 5 is increased because a natural frequency of the shaking of the construction 20 and a natural frequency of the lateral oscillation of the main rope 5 match each other. Through control for preventing the matching between the natural frequencies, the vibration of the car 1 can be suppressed. The event is comprehended as a single string vibration, and the natural frequency of the lateral oscillation of the main rope 5 is calculated by the following expression.
In Expression 1, v represents the natural frequency of the lateral oscillation of the main rope 5, l represents a length of the vibrating main rope 5, ρ represents a linear density of the main rope 5, and T represents the tension applied to the main rope 5.
From Expression 1, it is understood that the natural frequency can be freely changed through the control of the tension. Accordingly, as illustrated in the processing flow for the service mode in
Further, in this embodiment, the detection of the shaking of the construction 20 and the detection of the vibration of the car 1 are associated with each other. However, the same effects are obtained even in the following manner. In the first embodiment of
In this case, the tension of the main rope 5 is required to be controlled with attention focused on the fact that the frequency of the lateral oscillation of the main rope 5 is detected as half of a frequency of vertical oscillation of the main rope 5. Specifically, after the main rope tension is regulated assuming that the construction 20 shakes side-to-side in a period equal to half of the frequency of the main rope 5, which is to be detected, the natural frequency of the lateral oscillation is required to be controlled.
As described above, in the elevator device according to the third embodiment of the present invention, through the control of the natural frequency of the main rope, the resonance of the main rope is suppressed even when the construction shakes due to, for example, the earthquake or the strong wind. As a result, the effect of preventing the collision of the main rope against the device in the hoistway so as not to damage the device in the hoistway is obtained.
1 car, 2 counterweight, 3 hoisting machine, 4 sheave, 5 main rope, 6 car rail, 7 counterweight rail, 8 car brake device, 9 elevator controller, 9a hoisting-machine controller, 9b car brake controller, 10 tension detection device, 11 load detection device, 12 shaking detection device, 20 construction
Number | Date | Country | Kind |
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JP2017-027831 | Feb 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/001039 | 1/16/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/150786 | 8/23/2018 | WO | A |
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Entry |
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International Search Report and Written Opinion dated Mar. 6, 2018 for PCT/JP2018/001039 filed on Jan. 16, 2018, 11 pages including English Translation of the International Search Report. |
Number | Date | Country | |
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20200002134 A1 | Jan 2020 | US |