The present invention relates to an emergency stop system for an elevator, for braking a car going up and down in a shaft for an emergency stop.
For a conventional elevator, there has been proposed a method of controlling a braking force of an electromagnetic brake to set a deceleration of a car at an emergency stop to a predetermined value based on a deceleration command and a speed signal (for example, see Patent Document 1). By this method, the elevator can stop at the deceleration neither too high nor too low even at the emergency stop to prevent a human body from being affected by an excessive deceleration. Therefore, even on the end floor, the elevator can stop within an allowable stop distance.
The conventional example has a problem in that the high reliability of a control system or a state sensor is not ensured, and therefore the control system or the state sensor cannot be adapted to a product.
The present invention is devised to solve the problem as described above and has an object to provide an emergency stop system for an elevator, which compares two-or-more-system state sensors and control systems to detect a failure in the control systems or the state sensors without fail to stop braking force control at the occurrence of the failure or to use a normal system, thereby safely braking an elevator even at the occurrence of the failure to cause the elevator to make an emergency stop.
An emergency stop system for an elevator according to the present invention includes: a state sensor for detecting an operation of a car; a brake device for braking the car; a brake controller for outputting a signal for operating the brake device based on a signal detected by the state sensor; and an uninterruptible power supply device for supplying electric power to the state sensor, the brake device, and the brake controller, in which: the brake controller includes: a signal processing/calculating unit for calculating a deceleration of the car based on the signal detected by the state sensor; a command value calculating unit for calculating a command value for operating the brake device based on the deceleration of the car, which is calculated by the signal processing/calculating unit; and a power monitoring device for monitoring a state of the uninterruptible power supply device; and at least any one of the state sensor, the signal processing/calculating unit, and the command value calculating unit has a plurality of independent systems.
The emergency stop system for an elevator according to the present invention detects a failure in a control system or a state sensor without fail through the comparison between the results output from multiple detection means and calculation means to stop braking force control or to use a normal system at the occurrence of a failure. As a result, the emergency stop system for an elevator has the effect of safely braking the elevator even at the occurrence of the failure to cause the elevator to make an emergency stop.
Hereinafter, a first embodiment and a second embodiment of the present invention will be described.
An emergency stop system for an elevator according to the first embodiment of the present invention will be described referring to
In
Since the emergency stop system for an elevator has an object to control a deceleration, a speed, and a position of the car 15 according to determined target values, the emergency stop system for an elevator includes a state sensor for detecting a deceleration, a speed, or a position of a part moving in tandem with the car 15 or a load applied to the counterweight 14 or the car 15. The emergency stop system for an elevator according to the first embodiment has independent two-system encoders corresponding to a first speed governor encoder (first state sensor) 1 and a second speed governor encoder (second state sensor) 2, and estimates the movement of the car 15 based on the decelerations detected by the speed governor encoders or the like. Signals detected by the two-system speed governor encoders 1 and 2 are input to a brake controller 31.
The brake controller 31 outputs signals for operating the brake to a first brake coil 23 and a second brake coil 24 based on the signals detected by the speed governor encoders 1 and 2. In this first embodiment, a so-called electromagnetic brake is supposed as a brake device. The brake device pushes braking members (first brake plunger 21 and second brake plunger 22) against a member to be braked (brake pulley 25) with an elastic force of an elastic member to brake the member to be braked with a friction force. When the circuits (first brake coil 23 and second brake coil 24) are energized, an electromagnetic force acts on the braking members 21 and 22 in a direction reacting against the elastic force to separate the braking members 21 and 22 from the member to be braked 25. When a power supply from the power source is shut off, the brake device brakes the car 15 with the maximum braking force.
Next, an operation of the emergency stop system for an elevator according to this first embodiment will be described referring to the drawings.
The brake controller 31 receives an emergency stop command signal from an elevator operating device such as a control board to start the operation based on the received signal (Step 101).
The power monitoring device 43 monitors a state of electric power supplied from the uninterruptible power supply device 32 to the entire brake control system. When the supplied electric power is unstable, the power monitoring device 43 feeds a power fail signal for stopping the brake control to the command calculating unit 42 (Step 102).
The sensor signal processing unit 41 calculates deceleration of the car based on the signals detected by the first speed governor encoder 1 and the second speed governor encoder 2. The sensor signal processing unit 41 has two-system signal processing/calculating units corresponding to a first signal processing/calculating unit 51 and a second signal processing/calculating unit 52, each independently performing a calculation. First, each of the signal processing/calculating units 51 and 52 calculates a state quantity of the elevator, such as the deceleration based on the signals obtained from the speed governor encoders 1 and 2. The results are compared in each of the calculating units to detect a malfunction of the encoder. For example, when a difference between the state quantity calculated by the two-system encoders 1 and 2 the state quantity calculated by the two-system encoder 2 is smaller than a predetermined value in the first signal processing/calculating unit 51, or is less than the predetermined value (first predetermined value), it can be determined that the both encoders 1 and 2 operate normally. When the difference is larger than the predetermined value, or is equal to or larger than the predetermined value (first predetermined value), it can be determined that at least one of the encoders malfunctions (Step 103). The same process is performed in the second signal processing/calculating unit 52.
Next, when each of the encoders 1 and 2 operates normally, the state quantities of the elevator, which are calculated by the signal processing/calculating units 51 and 52, respectively, are compared with each other to determine that the calculations are correct. The first signal processing/calculating unit 51 calculates the state quantities of the elevator, such as the decelerations based on the signals obtained from the speed governor encoders 1 and 2 to compare an average value of the state quantities with an average value of the state quantities of the elevator, which are calculated by the second signal processing/calculating unit 52. Similarly, the second signal processing/calculating unit 52 calculates the state quantities of the elevator, such as the decelerations based on the signals obtained from the speed governor encoders 1 and 2 to compare an average value of the state quantities with an average value of the state quantities of the elevator, which are calculated by the first signal processing/calculating unit 51. Even in this case, when a difference between the state quantities calculated by the two-system signal processing/calculating units 51 and 52 is smaller than a predetermined value, or is less than the predetermined value (second predetermined value), it can be determined that the signal processing/calculating units 51 and 52 both operate normally. When the difference is larger than the predetermined value, or is equal to or larger than the predetermined value (second predetermined value), it can be determined that at least one of the signal processing/calculating units malfunctions (Step 104).
When it is determined that the speed governor encoders 1 and 2 and the signal processing/calculating units 51 and 52 all operate normally, the sensor signal processing unit 41 outputs, for example, the average value of the state quantities of the elevator, which are calculated by the first signal processing/calculating unit 41 and the second signal processing/calculating unit 52, respectively, to the command calculating unit 42. Processing of obtaining the average value in a plurality of systems is the same in the other processing or in a second embodiment. It should be noted that in some cases, any one of the state quantities of the elevator, which are calculated by the first signal processing/calculating unit 51 and the second signal processing/calculating unit 52, respectively, may be output to the command calculating unit 42. The same is applied to the other processing or the second embodiment. When it is determined that any of the speed governor encoders 1 and 2 and the signal processing/calculating units 51 and 52 does not operate normally, the sensor signal processing unit 41 feeds a detection fail signal for stopping the brake control to the command calculating unit 42.
Next, the command calculating unit 42 calculates a command value for operating the brake and gives commands to the brake and the power source. The command calculating unit has two-system command value calculating units corresponding to a first command value calculating unit 61 and a second command value calculating unit 62, each independently calculating the command value to be provided for the brake. If the detection fail signal or the power fail signal is not input to the command calculating unit 42, the command values each are calculated by the command value calculating units 61 and 62 based on the state qualities of the elevator. The command values calculated by the two command value calculating units are compared with each other to determine that the calculations in the command value calculating units are correct. Even in this case, as being performed in the signal processing/calculating units, when a difference between the state quantities calculated by the two-system command value calculating units 61 and 62 is smaller than a predetermined value, or is less than the predetermined value (third predetermined value), it is determined that the command value calculating units both operate normally to calculate the command values normally. When the difference is larger than the predetermined value, or is equal to or larger than the predetermined value (third predetermined value), it is determined that at least anyone of the command value calculating units malfunctions to prevent the command values from being normally calculated (Step 105).
When it is determined that the command value calculating units 61 and 62 operate normally, an average value of the each calculated brake operation commands is fed from the brake controller 31 to the brake device (Steps 106 and 107). In this case, the brake device is required to be controlled after the determination of a target value which can realize a deceleration which does not adversely affect a passenger in the car 15 and the elevator system, and when the brake controller 31 has information of the position of the car, is moderated within the range that avoids the car 15 from entering the end of a shaft.
When it is determined that the command value is not calculated normally or the detection fail signal or the power fail signal is input, the brake coils 23 and 24 are de-energized. Further, a signal for stopping power feeding from the uninterruptible power supply device 32 is output to the uninterruptible power supply device 32 to shut off the power supply itself. As a result, it can be ensured that the car is prevented from entering the end of the shaft at a dangerous speed.
The uninterruptible power supply device 32 can supply electric power even in an emergency and has power storage ability. When a normal power source is not available, the stored power is supplied. Moreover, if it is determined that the stored power is always used in an emergency, the amount of power supply for keeping the brake in a released state is limited. As a result, since the upper limit of a time period, in which the brake is in the released state, can be ensured, added safety is ensured.
In addition, as a method of further enhancing the safety of the emergency stop system for an elevator, the following methods are conceived. In one method, the brake controller 31 has a timer function. After an elapse of a given period of time, or when the deceleration after an elapse of a given period of time is smaller than a predetermined value, a brake command is output. In another method, the brake command is output when a speed becomes excessively high. In this case, as a cycle used for the timer function, the use of a clock cycle of a CPU or a quartz frequency is given.
In this first embodiment, the brake coils 23 and 24 are de-energized or the power supply from the uninterruptible power supply device 32 is shut off based on the output signal from the command calculating unit 42. When a problem is detected in the power monitoring device 43 or the sensor signal processing unit 41, a command may be directly output from the power monitoring device 43 or the sensor signal processing unit 41 to effect de-energization or to shut off the power supply.
The signals obtained by detecting the rotations of the speed governor 16 with the encoders 1 and 2 are used to calculate the deceleration of the car 15, but a signal obtained by detecting, with a sensor, another part moving in tandem with the car 15, for example, the amount of rotation of the sheave 12, the amount of feeding of the main rope 13, or the amount of upward/downward movement of the counterweight 14 or the car 15 illustrated in
The electromagnetic brake is supposed as the brake used for braking in this first embodiment, but other brakes such as a hydraulic brake may be used as long as the brake can change a torque.
For calculating the command value in the command calculating unit 42, so-called PID control for calculating the command value from a proportional element, a time integration element, and a time differentiation element of a difference between the target value and the detected value may be used. Moreover, in the case where the value to be detected is the deceleration, there may be used a method of giving a command to reduce the braking force when the detected value is larger than the target deceleration and giving a command to increase the braking force when the detected value is smaller than the target deceleration. In the former case, highly accurate deceleration control can be expected according to the system. Since two command values are provided and only the switching between the two command values enables the highly-accurate deceleration control in the latter case, the latter case has an advantage in that the configuration is not complicated.
The case where the two-system state sensors or calculating units are prepared and the results are compared to ensure the reliability has been described in the first embodiment. However, a one-system state sensor or calculating unit is provided if the reliability of the safety system is ensured only with the one-system state sensor or calculating unit. Accordingly, the cost can be reduced.
If the uninterrupted power source unit 32 includes independent two-system power sensors 71 and 72 and the power monitoring device 43 includes independent two-system power signal processing/calculating units 81 and 82 as illustrated in
An emergency stop system for an elevator according to the second embodiment of the present invention will be described referring to
In
Next, an operation of the emergency stop system for an elevator according to this second embodiment will be described referring to the drawing.
The operation of the brake controller in the determination of the emergency stop command (Step 201) and the determination of the safety of the power source (Step 202) is the same as the operation in the determination of the emergency stop command (Step 101 of
The sensor signal processing unit 41 calculates the deceleration of the car based on the signals detected by the speed governor encoders 1, 2, and 3. The sensor signal processing unit 41 has the three-system signal processing/calculating units 51, 52, and 53, each independently performing a calculation. First, each of the signal processing/calculating units 51, 52, and 53 calculates the state quantity of the elevator, such as the deceleration based on the signals obtained from the speed governor encoders 1, 2, and 3. The results are compared in each of the calculating units to detect a malfunction of the encoder. In the comparison, when a difference between the state quantities calculated by using the encoder signals from each two-system is smaller than the predetermined value, or is less than the predetermined value (first predetermined value), it is determined that both encoders operate normally. When the difference is larger than the predetermined value, or is equal to or larger than the predetermined value (first predetermined value), it is determined that at least any one of the encoders malfunctions. By providing the three-system encoders, even when it is determined that one-system encoder malfunctions, the encoder signals from the remaining two-system encoders can be used to perform control (Steps 203 to 208).
When two-or-more-system encoders operate normally, the signals from the encoders which operate normally are used to calculate the necessary state quantities of the elevator in the signal processing/calculating units 51, 52, and 53. The results of the calculations are compared with each other to determine that the calculations in the signal processing/calculating units 51, 52, and 53 are correct. Even in this case, the comparison is performed between the results of the calculations of each two-system. When a difference between the calculated state quantities is smaller than the predetermined value, or is less than the predetermined value (second predetermined value), it is determined that the signal processing/calculating units both operate normally. When the difference is larger than the predetermined value, or is equal to or larger than the predetermined value (second predetermined value), it is determined that at least any one of the signal processing/calculating units malfunctions. By providing the three-system calculating units, even if it is determined that a one-system signal processing/calculating unit malfunctions, the results in the remaining two-system signal processing/calculating units can be used to perform the control (Steps 209 to 214).
As in the sensor signal processing unit 41, when three-system command value calculating units are provided and compared with each other to confirm that the two-system command value calculating units operate normally in the command calculating unit 42, only the results of processing in the command value processing units which operate normally can be used to perform the control even if a failure occurs in the remaining one-system command value calculating unit (Steps 215 to 220).
The sensor signal processing unit 41 outputs the state quantity of the elevator used for the control when two-or-more-system speed governor encoders of the speed governor encoders 1, 2, and 3 and two-or-more-system signal processing/calculating units of the signal processing/calculating units 51, 52, and 53 operate normally. The sensor signal processing unit 41 outputs the detection fail signal to the command calculating unit 42 when two-or-more-system speed governor encoders of the speed governor encoders 1, 2, and 3 or two-or-more-system signal processing/calculating units of the signal processing/calculating units 51, 52, and 53 malfunction.
For the uninterrupted power source unit 32 and the power monitoring device 43, the following method may be used. Three-system power sensors 71, 72, and 73 and three-system power signal processing/calculating units 81, 82, and 83 are provided as illustrated in
Further, when four-or-more-system sensors or calculating units are provided and compared with each other to confirm that two-or-more-system sensors or calculating units operate normally, a method of operating the command calculating unit 42 by using only the results of processing in the calculating units which operate normally may be used even if a failure occurs in two-or-more-system calculating units. As the number of systems for the sensor or the calculating unit to be used, any of a method of using three-or-more-system sensors or the calculating units as described in this second embodiment and a method of using two-system sensors or calculating units as described in the first embodiment above can be selected in accordance with the degree of reliability of the sensors and the calculating units and the degree of safety required for the system.
When three-or-more-system sensors or calculating units are provided, there is used a method of comparing the sensors or the calculating units to operate the elevator only when the three-or-more-system sensors or calculating units operate normally and to stop the operation when a failure occurs in a part of the sensors or the calculating units and only two-system sensors or calculating units operate normally to enable a safer operation. In this case, the brake is not forcibly stopped by the power shutoff without control as in the above-mentioned case where the electromagnetic brake is used, and the brake can be controlled at any time.
The case where the three-system sensors and the three-system calculating units are prepared and the results are compared to ensure the reliability has been described in this second embodiment, but two- or one-system state sensor(s) or calculating unit(s) is/are provided if the two- or one-system state sensor(s) or calculating unit(s) can ensure the reliability of the safety system. Accordingly, the cost can be reduced.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2005/021710 | 11/25/2005 | WO | 00 | 5/27/2008 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2007/060733 | 5/31/2007 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4750591 | Coste et al. | Jun 1988 | A |
5360952 | Brajczewski et al. | Nov 1994 | A |
6173814 | Herkel et al. | Jan 2001 | B1 |
6196355 | Fargo et al. | Mar 2001 | B1 |
6516922 | Shadkin et al. | Feb 2003 | B2 |
7334665 | Smith et al. | Feb 2008 | B2 |
7350624 | Deplazes et al. | Apr 2008 | B2 |
7448471 | Nuebling | Nov 2008 | B2 |
7540358 | Okamoto et al. | Jun 2009 | B2 |
20060157305 | DePlazes et al. | Jul 2006 | A1 |
20090223748 | Mustalahti et al. | Sep 2009 | A1 |
20100038185 | Kattainen et al. | Feb 2010 | A1 |
Number | Date | Country |
---|---|---|
2 153 465 | Aug 1985 | GB |
60-148879 | Aug 1985 | JP |
3-13467 | Jan 1991 | JP |
7-157211 | Jun 1995 | JP |
7-206288 | Aug 1995 | JP |
2002-241062 | Aug 2002 | JP |
Number | Date | Country | |
---|---|---|---|
20090266649 A1 | Oct 2009 | US |