JP2008068965A - Elevator device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an elevator device capable of preventing occurrence of overshooting target deceleration at emergency braking time and occurrence of delay in reaching the target deceleration. <P>SOLUTION: Brake devices 9a, 9b are controlled by a brake controller 19, which can control deceleration of a car 1 by referring to a signal from a hoisting machine encoder 12 to infer speed and deceleration of the car, applying voltages to brake coils 11a, 11b based on the results of inference, and adjusting the force for pressing brake shoes 10a, 10b against a brake wheel 8 at the emergency braking time. The brake controller 19 changes how to rise (quick or slow) of braking force of the brake devices 9a, 9b at the emergency braking time in accordance with a running condition of the car 1 when an emergency stop order is given. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an elevator apparatus having a brake control device capable of controlling a braking force during emergency braking.

  In the conventional elevator apparatus, the deceleration of the car is variably controlled by controlling the energization current to the brake coil at the time of emergency stop. At the time of an emergency stop, a speed command based on an emergency stop speed reference pattern having a predetermined deceleration is output from the speed reference generation unit (see, for example, Patent Document 1).

JP-A-7-206288

  However, in the conventional elevator apparatus as described above, the braking force is controlled so that the car deceleration at the time of emergency stop becomes a predetermined value based only on the deceleration signal, and the car changes depending on the loading state of the car. Control is not performed in consideration of the weight difference with the counterweight, so overshoot from the target deceleration and delay to reach the target deceleration occur, and the deceleration cannot be reduced sufficiently, and the stopping distance is It could be long.

  The present invention has been made to solve the above-described problems, and is an elevator that can prevent the occurrence of overshoot from the target deceleration during emergency braking or the arrival delay to the target deceleration. The object is to obtain a device.

  An elevator apparatus according to the present invention includes a car, a brake device that brakes the traveling of the car, a brake control device that controls the braking force of the brake device during emergency braking, a loaded weight detection unit that detects the loaded weight of the car, and the traveling of the car The brake control device has a braking force required to stop the car within the allowable stop distance based on the weight of the car when the emergency stop command is generated and the running direction. When the required braking force is large, the rising of the braking force of the brake device is made rapid, and when the necessary braking force is small, the rising of the braking force of the brake device is made slow.

  In the elevator apparatus according to the present invention, whether the braking force required for the brake control device to stop the car within the allowable stop distance is large or small based on the load weight and traveling direction of the car when the emergency stop command is generated. When the required braking force is large, the braking device rises quickly, and when the required braking force is small, the braking device rises slowly. It is possible to prevent the occurrence of overshoot from the target deceleration and the arrival delay to the target deceleration.

The best mode for carrying out the present invention will be described below with reference to the drawings.
Embodiment 1 FIG.
1 is a block diagram showing an elevator apparatus according to Embodiment 1 of the present invention. In the figure, a car 1 and a counterweight 2 are suspended in a hoistway by a main rope (suspension means) 3 and are raised and lowered in the hoistway by a driving force of a hoisting machine 4. The hoist 4 includes a drive sheave 5 around which the main rope 3 is wound, a motor 6 that rotates the drive sheave 5, and braking means 7 that brakes the rotation of the drive sheave 5.

  The braking means 7 includes a brake wheel 8 that is rotated integrally with the drive sheave 5, and first and second brake devices 9 a and 9 b that brake the rotation of the brake wheel 8. As the brake wheel 8, a brake drum or a brake disc is used. The drive sheave 5, the motor 6 and the brake wheel 8 are provided on the same axis.

  The first brake device 9a includes a first brake shoe 10a that is brought into contact with and separated from the brake wheel 8, a first brake spring that presses the first brake shoe 10a against the brake wheel, and a first brake shoe 10a against the first brake spring. And a first electromagnetic magnet that is separated from the brake wheel 8. The first electromagnetic magnet has a first brake coil (electromagnetic coil) 11a that is excited by being energized.

  The second brake device 9b includes a second brake shoe 10b that contacts and separates from the brake wheel 8, a second brake spring that presses the second brake shoe 10b against the brake wheel, and a second brake shoe 10b that opposes the second brake spring. And a second electromagnetic magnet that is separated from the brake wheel 8. The second electromagnetic magnet has a second brake coil (electromagnetic coil) 11b that is excited by being energized.

  By passing an electric current through the brake coils 11a and 11b, the electromagnetic magnet is excited, an electromagnetic force for releasing the braking force of the brake devices 9a and 9b is generated, and the brake shoes 10a and 10b are separated from the brake wheel 8. It is. Further, by deenergizing the brake coils 11a and 11b, the excitation of the electromagnetic magnet is released, and the brake shoes 10a and 10b are pressed against the brake wheel 8 by the spring force of the brake spring. Furthermore, the degree of opening of the brake devices 9a and 9b can be controlled by controlling the current value flowing through the brake coils 11a and 11b.

  The motor 6 has a hoisting machine encoder 12 as a traveling direction detection means, an acceleration detection means, a speed detection means, and a position detection means for generating a signal corresponding to the rotation speed of the rotation shaft, that is, the rotation speed of the drive sheave 5. Is provided.

  A speed governor 13 is installed in the upper part of the hoistway. The governor 13 includes a governor sheave 14 and a governor encoder 15 that generates a signal corresponding to the rotational speed of the governor sheave 14. A governor rope 16 is wound around the governor sheave 14. Both ends of the governor rope 16 are connected to an operation mechanism of an emergency stop device mounted on the car 1. The lower end portion of the governor rope 16 is wound around a tension wheel 17 disposed at the lower part of the hoistway.

  The drive of the hoist 4 is controlled by the elevator control device 18. That is, the raising / lowering of the car 1 is controlled by the elevator control device 18. The brake devices 9a and 9b are controlled by a brake control device 19. Signals from the elevator control device 18 and the hoisting machine encoder 12 are input to the brake control device 19. At the upper part of the car 1, a car scale device 20 is provided as a load weight detecting means for outputting a signal corresponding to the load weight of the car 1.

  FIG. 2 is a block diagram showing the brake control device 19 of FIG. The brake control device 19 includes a signal processing unit 21, a command calculation unit 22, and a command output unit 23 inside. The signal processing unit 21 receives signals from the elevator control device 18 and the hoisting machine encoder 12, and based on the signals, estimates an emergency braking state and estimates state quantities such as the position, speed, and deceleration of the car 1. The result is transmitted to the command calculation unit 22. Based on the result received from the signal processing unit 21, the command calculation unit 22 calculates the applied voltage to the brake coils 11a and 11b for stopping the car 1 at the target deceleration, and the result is output to the command output unit. 23. The command output unit 23 applies a voltage to the brake coils 11 a and 11 b based on the result received from the command calculation unit 22. As a result, electromagnetic force is generated in the brake coils 11a and 11b, and the force of pressing the brake shoes 10a and 10b against the brake wheel 8 can be adjusted to appropriately control the deceleration of the car 1.

  Further, the brake control device 19 changes the way in which the braking force of the brake devices 9a and 9b during emergency braking rises (agility) according to the state of the car 1 when the emergency stop command is generated. Specifically, when the braking force necessary for stopping the car 1 within the allowable stopping distance is large, the brake control device 19 promptly raises the braking force of the braking devices 9a and 9b, and the necessary braking force is increased. When it is small, the rise of braking force is slowed down.

  Here, FIG. 3 is a graph showing the operation of the brake shoes 10a and 10b when an emergency stop is performed without controlling the braking force. In this case, when an emergency stop command is generated at time T1, the brake gap between the brake shoes 10a, 10b and the brake vehicle 8 is reduced at a stretch. At time T2, the brake shoes 10a and 10b come into contact with the brake wheel 8 and a braking force is generated.

  When the car 1 is in an emergency stop, the motor 6 is also de-energized, so that the car 1 is accelerated between time T1 and time T2 due to an imbalance between the load on the car 1 side and the load on the counterweight 2. And the car 1 may be decelerated.

  FIG. 4 is a graph showing changes in car speed and car deceleration over time when an emergency stop is performed without controlling the braking force. The car speed is indicated by positive in the vertical direction, and the car deceleration is indicated by positive in the traveling direction.

  In FIG. 4, a fine broken line (1) indicates a case where the load weight is large when descending or a case where the load weight is small when ascending. In this case, the car 1 is accelerated between time T1 and time T2. A solid line (2) indicates a case where the car 1 side and the counterweight 2 side are balanced. In this case, the car 1 substantially maintains the speed when the emergency stop command is generated between the time T1 and the time T2. A rough broken line (3) indicates a case where the load weight is small when descending or a case where the load weight is large when ascending. In this case, the car 1 is decelerated between time T1 and time T2.

  FIG. 5 is a graph showing the time change of the car speed and the car deceleration when the braking force control is performed to make an emergency stop. In the example of FIG. 5, the braking force is controlled so that the average deceleration during emergency braking becomes the target deceleration rate α0.

  In general, the braking devices 9a and 9b used for emergency braking have a rapid rise in braking force. Therefore, when the weight difference between the car 1 and the counterweight 2 acts in the deceleration direction (broken line (3)), a large overshoot from the target value occurs immediately after the braking force is generated. In order to prevent such overshoot, there is a method of slowing the rising of the braking force. However, in this method, the stop distance becomes long, and the allowable stop distance may be exceeded in the case of the broken line (1).

  On the other hand, FIG. 6 is a graph showing time changes of the car speed and the car deceleration when the braking force control is performed by the brake control device 19 of FIG. As described above, the brake control device 19 according to the first embodiment provides the brake devices 9a and 9b when the braking force required to stop the car 1 within the allowable stop distance is smaller than when the braking force is large during emergency braking. The rise of braking force is slowed down.

  Whether or not the braking force required at the time of emergency braking is small can be determined from the loading state of the car 1 when the emergency stop command is generated and the traveling direction of the car 1. Further, the braking force required during emergency braking can be estimated based on the loading state of the car 1 when the emergency stop command is generated, the traveling direction of the car 1, and a preset target deceleration rate α0. Further, the braking force required during emergency braking is small when the car 1 is decelerated between time T1 and time T2, and is large when the car 1 is accelerated.

  Although the weight difference between the car 1 and the counterweight 2 varies depending on the loading state of the car 1, when the weight difference works in the direction opposite to the traveling direction, there is no braking force by the brake devices 9a and 9b. Even the car 1 decelerates. In such a case, if the rise of the braking force is a quick characteristic, the braking force rises more than necessary, and an overshoot from the target deceleration rate α0 occurs.

  Also, under such conditions that overshoot from the target deceleration α0 occurs, the car 1 also decelerates during the idle running time (T1 to T2) until the braking force is generated, so there is a margin before the allowable stop distance. In addition, the car 1 can be stopped within the allowable stopping distance even when the braking force rises slowly.

  Therefore, in the first embodiment, as shown by the solid line (2) and the broken line (3), the rising of the braking force is slowed under the condition that the braking force can be stopped within the allowable stopping distance even if the rising of the braking force is slower than the conventional one. To do. Thereby, overshoot can be reduced.

  On the other hand, under the condition of the broken line (1), the force due to the weight difference acts in the direction of accelerating the car 1, so there is no overshoot from the target deceleration α0 and the rise of the braking force is slow. Then, since the vehicle cannot be stopped within the allowable stop distance, the braking force is quickly raised as before.

  FIG. 7 shows a flowchart for determining the rise of the brake braking force at the time of emergency stop. In the flowchart, first, an emergency determination (S1) is performed, and then the loaded weight is compared with a reference weight (S2) to determine the direction in which the weight difference between the car 1 and the counterweight 2 works. Then, taking into account the direction of travel (S3, S4), if the weight difference works to increase the speed of the car relative to the direction of travel, the brake will start quickly, and if it works to decelerate, the brake will start. To slow down. After the rise of the braking force is determined, the process proceeds to braking force control. Here, the reference weight is determined so that there is no difference in weight between the car 1 and the counterweight 2 when the loaded weight is equal to the reference weight.

  In the first embodiment, the brake control device 19 determines whether the force due to the weight difference acts in the acceleration direction or the deceleration direction based on the information on the loaded weight and the information on the traveling direction of the elevator control device 18. . When the force due to the weight difference acts in the deceleration direction, a command is given to the brake coils 11a and 11b so that the rising of the braking force becomes slow. In addition, when the force due to the weight difference works in the acceleration direction, a command is given to the brake coils 11a and 11b so that the rising of the braking force is quick.

  Here, a method using the car balance device 20 as the load weight detection means has been described. However, the coil current value of the motor 6 during travel may be referred to from the elevator control device 18 to estimate the load weight from the travel load. .

  Further, in order to change the rapidity of the rising of the braking force, for example, when using an electromagnetic brake as in the first embodiment, the rapidity of the current drop of the brake coils 11a and 11b at the time of emergency stop is changed. There is a way. By changing the rapidity of the current drop, the quickness of the rise of the pressing force of the brake shoes 10a and 10b by the brake spring at the time of emergency stop also changes, and the quickness of the rise of the braking force can be changed.

  As a specific example of the method of changing the rapidity of the current drop of the brake coils 11a and 11b, the applied voltage is normally cut off immediately during an emergency stop, whereas the applied voltage is lowered stepwise to reduce the braking force. Examples thereof include a method of slowing up the rising and a method of applying a voltage in the direction opposite to the direction of voltage application at the time of raising the brake to make the braking force rise quickly. Moreover, current reduction can be made quick by connecting current resistance to both ends of the brake coils 11a and 11b and circulating current between the brake coils 11a and 11b and the current resistance.

  Furthermore, comparing FIGS. 4 to 6, it can be seen that the acceleration / deceleration relationship between time T1 and time T2 is the same regardless of the presence or absence of control. This is because at time T1 to T2, the braking force of the brake devices 9a and 9b has not yet been generated, and only the force due to the weight difference between the car 1 and the counterweight 2 is acting on the car 1. .

  For this reason, when the weight difference acts in the acceleration direction as indicated by the broken line (1), the deceleration becomes negative and the speed increases. On the other hand, when the weight difference acts in the deceleration direction as indicated by the broken line (3), the deceleration becomes positive and the speed decreases.

  Therefore, the acceleration / deceleration of the car 1 between the time T1 and the time T2 is detected, and how the braking force rises before the time T2 is determined according to whether the car is in an acceleration state or a deceleration state. May be. Even with such a method, it is possible to reduce the overshoot from the target deceleration while stopping the car 1 within the allowable stopping distance. In addition, in this case, it is possible to perform the deceleration control taking into consideration the loading state based only on the speed signal.

  Further, how to raise the braking force may be determined according to the speed or position of the car 1 after a predetermined time from the time T1. However, the predetermined time t ≦ T2-T1.

  As a method of obtaining the car deceleration, the car speed, and the car position, a signal from the hoisting machine encoder 12 or the governor encoder 15 may be used, or fishing linked to the raising / lowering of the car 1 or the car 1. You may utilize the signal from the detector provided separately in the weight 2 grade | etc.,. At this time, since the signal value may become oscillating due to the influence of the elastic body such as the main rope 3, for example, a filtering process such as a low-pass filter may be performed as necessary.

Here, the calculation of the loading state in the configuration in the first embodiment can be specifically performed based on the following concept. That is, if the car weight is m1, the loaded weight is m2, the counterweight weight is m3, the other inertial mass is m4, and the car deceleration between time T1 and time T2 is α1, the following equation of motion holds. However, g is a gravitational acceleration.
(M1 + m2 + m3 + m4) α1 = ± (m1 + m2−m3) g (i)

Therefore, based on the equation (i), the loading weight m2 can be calculated as the following equation.
m2 = {± (m3−m1) g + (m1 + m3 + m4) α1} / (± g−α1) (ii)

The positive and negative signs in the expressions (i) and (ii) are positive when rising and negative when falling. Α1 can be calculated from the following equation, where t1 is the elapsed time from time T1 to time T2, v1 is the car speed at time T1, and v2 is the car speed at time T2.
α1 = (v2−v1) / t1 (iii)

Furthermore, when the travel distance L1 of the car 1 from the time T1 to the time T2 is used instead of v2, it can also be calculated from the following equation.
α1 = 2 (L1−v1t1) / t1 ² (iv)

  According to such a method, the loading state can be grasped without newly adding a scale device or a device for performing signal processing of the scale device.

In the configuration of the first embodiment, the braking force required according to the target deceleration can be specifically calculated based on the following concept. That is, when the braking force term F by the brake devices 9a and 9b is added to the equation (i) representing the equation of motion of the elevator device, the equation after the braking force is generated with the target deceleration being α0 is obtained as follows.
(M1 + m2 + m3 + m4) α0 = ± (m1 + m2-m3) g + F (v)

From equation (iii), the required braking force F when the target deceleration is α0 is obtained as follows.

  By using the load weight estimated by the equation (ii) as the load weight term m2 in the equation (vi), the load state is grasped without using the scale device, and the car is calculated with the braking force calculated based on the load state. By stopping 1, it is possible to stop at an appropriate deceleration. Further, the sign in the equation (v) is positive when rising and negative when falling, and the sign in equation (vi) is negative when rising and positive when falling.

  In the first embodiment, the brake coils 11a and 11b are realized by the brake control device 19 so as to realize the braking force calculated from the equation (vi) based on the information from the hoisting machine encoder 12 and the information on the traveling direction. Is given a directive. As a specific method for realizing the calculated braking force, for example, when a plurality of sets of electromagnetic brakes are used as in the first embodiment, a part of the brake coils 11a is energized and the power of the remaining brake coils 11b is used. For example, a method of adjusting the braking force by changing the number of electromagnetic brakes that perform a braking operation, such as blocking. Further, the braking force may be adjusted by adjusting the pressing force of all the brake shoes 10a and 10b by simultaneously adjusting the energization currents to all the brake coils 11a and 11b.

  In such an elevator device, the brake control device 19 changes how the braking force of the brake devices 9a and 9b during emergency braking rises according to the traveling state of the car 1 when the emergency stop command is generated. It is possible to prevent the occurrence of overshoot from the target deceleration and the arrival delay to the target deceleration.

  The brake control device 19 makes the rising of the braking force quick when the braking force necessary to stop the car 1 within the allowable stopping distance is large, and slows the rising of the braking force when small. Accordingly, it is possible to more reliably prevent the occurrence of overshoot from the target deceleration during emergency braking or the arrival delay to the target deceleration.

Furthermore, since the brake control device 19 determines the magnitude of the required braking force based on the loading state of the car 1 and the traveling direction when the emergency stop command is generated, the selection of how to raise the braking force is easier and easier. Can be done quickly.
Furthermore, since the brake control device 19 calculates the necessary braking force from the loaded state of the car 1, the traveling direction, and the preset target deceleration, the control of the rising of the braking force and the vehicle deceleration are targeted. Control along the deceleration can be realized with high accuracy.
Further, the brake control device 19 estimates the loading state of the car 1 from the change in at least one of the acceleration, speed, and position of the car 1 immediately after the emergency stop command is generated. Therefore, it is not necessary to add a new weighing device, and braking force control can be realized at a low cost.
Furthermore, the brake control device 19 has a braking force higher than that when the car 1 is decelerated when the car 1 is decelerated between the occurrence of an emergency stop command and the generation of the braking force of the braking devices 9a and 9b. Make the rise slow. Accordingly, it is possible to more reliably prevent the occurrence of overshoot from the target deceleration during emergency braking or the arrival delay to the target deceleration.

In the above example, the brake devices 9a and 9b are provided in the hoisting machine 4, but may be provided in other positions. For example, the brake device may be a car brake mounted on a car, a rope brake that holds the main rope and brakes the car, or the like.
Moreover, you may make it detect an emergency braking operation | movement independently by a brake control apparatus irrespective of the signal from an elevator control apparatus.
Furthermore, the rapidity of the rising of the braking force may be set stepwise or continuously in accordance with the required braking force and the acceleration / deceleration of the car immediately after the emergency stop command is generated. For example, when the car is being accelerated immediately after the emergency stop command is generated, the degree of rapid increase in the braking force may be changed according to the acceleration. Further, when the car is decelerated immediately after the emergency stop command is generated, the degree of slowing down of the braking force may be changed according to the deceleration.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the elevator apparatus by Embodiment 1 of this invention. It is a block diagram which shows the brake control apparatus of FIG. It is a graph which shows operation | movement of the brake shoe at the time of emergency stop, without controlling braking force. It is a graph which shows the time change of the car speed and car deceleration in the case of emergency stop without controlling braking force. It is a graph which shows the time change of the car speed and car deceleration when braking force control is performed and an emergency stop is performed. It is a graph which shows the time change of the cage | basket | car speed and cage | basket deceleration at the time of performing emergency stop by performing braking force control by the brake control apparatus of FIG. It is a flowchart which shows the braking force determination operation | movement by the brake control apparatus of FIG.

Explanation of symbols

  1 car, 9a first brake device, 9b second brake device, 19 brake control device.

Claims (6)

Basket,
A brake device for braking the traveling of the car,
A brake control device for controlling the braking force of the brake device during emergency braking;
A load weight detection means for detecting the load weight of the car, and a travel direction detection means for detecting the travel direction of the car,
The brake control device determines whether the braking force required to stop the car within the allowable stopping distance is large or small based on the load weight and traveling direction of the car when the emergency stop command is generated. An elevator apparatus characterized in that when the braking force is large, the braking force of the braking device rises quickly, and when the necessary braking force is small, the braking force of the braking device slows down.   2. The elevator apparatus according to claim 1, wherein the brake control device calculates a necessary braking force from a load weight of the car, a traveling direction, and a preset target deceleration.   The said brake control apparatus estimates the loading weight of the said car from the change of at least any one of the acceleration of the said car immediately after emergency stop instruction | command generation | occurrence | production, speed, and a position. Elevator equipment. Basket,
A brake device for braking the traveling of the car,
A brake control device for controlling the braking force of the brake device during emergency braking, and an acceleration detection means for detecting the acceleration of the car,
When the car is accelerated immediately after the emergency stop command is generated, the brake control device makes the braking force rise of the brake device quick, and when the car is decelerated, the brake control device makes the brake force rising slowly. The elevator apparatus characterized by doing. Basket,
A brake device for braking the traveling of the car,
A brake control device for controlling the braking force of the brake device during emergency braking, and a speed detection means for detecting the speed of the car,
The brake control device estimates whether the car is decelerated or accelerated from the change in the speed of the car immediately after the emergency stop command is generated, and when the car is accelerated immediately after the emergency stop command is generated, An elevator apparatus characterized in that when the braking force of the brake device rises quickly and decelerates, the braking force of the brake device slows down. Basket,
A brake device for braking the traveling of the car,
A brake control device for controlling the braking force of the brake device during emergency braking, and a position detection means for detecting the position of the car,
The brake control device estimates whether the car is decelerated or accelerated from the change in the position of the car immediately after the emergency stop command is generated, and when the car is accelerated immediately after the emergency stop command is generated, An elevator apparatus characterized in that when the braking force of the brake device rises quickly and decelerates, the braking force of the brake device slows down.

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