KR102022235B1 - Elevator braking system - Google Patents

Abstract

The elevator braking device is provided so as to be rotatable with respect to the movable part 14 and the movable part 14 which are displaceable in the direction perpendicular to the guide rail 5 which is a braking surface, and the rotating sliding part which contacts a braking surface when it rotates. (16), a motor (20) for rotating the rotating sliding portion (16), an electromagnet (21) and a pressure spring (22) for displacing the rotating sliding portion (16) in a direction in contact with the braking surface when the power is cut off. In the normal operation, the rotating sliding portion 16 is rotated by the motor 20 to contact the rotating sliding portion 16 with the braking surface to maintain the braking surface. By turning off the electromagnet 21, the rotation sliding part 16 is made to contact a braking surface, and braking of a braking surface is performed.

Description

Elevator braking system

The present invention relates to an elevator braking device, and more particularly, to an elevator braking device that holds and brakes a car of an elevator.

In a general elevator, a car arranged in a hoistway is driven up and down by a drive device. In addition, when the car is stopped, the car is held at the stop position by the braking device. Further, even when any abnormality is detected while the car is running and the car is emergency stopped, the car is decelerated and stopped by braking by the braking device.

For example, Patent Document 1 describes a brake device that brakes and holds an elevator car. The brake apparatus of patent document 1 is equipped with the mount and eccentric mount comprised so that displacement with respect to the guide rail. Brake linings are provided in the mount and the eccentric mount. At the time of stopping in each normal floor, a braking force is obtained by fixing with guide rails between these brake linings. During an emergency stop, the eccentric mount rotates by releasing the fixation to the guide rail by the electromagnetic actuator. This generates a strong frictional force between the eccentric mount and the guide rail to stop the car.

Patent Document 1: Japanese Patent Laid-Open No. 2008-143706

In the brake apparatus shown in patent document 1, movement of a car is required in order to rotate an eccentric mount at the time of an emergency stop. Therefore, since the lowering of the car occurs at the time of holding the car at the stop position in each floor, it cannot be used for holding the car.

This invention is made | formed in order to solve such a subject, and an object of this invention is to obtain the elevator braking apparatus which can hold | maintain a car as well as the braking of a car.

The present invention provides a movable part that can be displaced in a vertical direction with respect to a braking surface as a target, and is rotatably provided with respect to the movable part, and is rotated by a predetermined rotational angle from a reference angle as a reference. Generating a first sliding force to rotate the rotary sliding portion with respect to the movable portion, a first driving portion for rotating the rotary sliding portion relative to the movable portion, and a first pressing force for displacing the movable portion in a direction in which the rotary sliding portion contacts the braking surface, A second driving part exerting a force that does not displace the movable part in a direction in which the rotating sliding part contacts the braking surface in response to the first pressing force; and when the power source of the second driving part is energized, The movable portion at a position where the pivot sliding portion in a state does not contact the braking surface It is an elevator braking device provided with the position adjustment part which generate | occur | produces the 2nd pressing force to hold.

According to the present invention, by rotating the rotary sliding portion directly by the first drive portion, even if there is no movement of the car, it is possible to obtain a high braking force due to the self-energizing effect, and can be operated by turning off the power. By providing a 2nd drive part, the elevator braking apparatus which can not only hold | maintain a car at the time of running of a car but also hold | maintain a car can be implement | achieved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the structure of the whole elevator system containing the elevator braking apparatus which concerns on Embodiment 1 of this invention.
It is a block diagram which shows the structure of the brake apparatus which concerns on Embodiment 1 of this invention.
It is a block diagram which shows the state which rotated the rotating sliding part which concerns on Embodiment 1 of this invention to upper direction.
4 is a configuration diagram showing a state in which an electromagnet according to Embodiment 1 of the present invention is blocked.
It is a block diagram which shows the state of the brake apparatus which implemented the emergency operation which concerns on Embodiment 1 of this invention.
It is a block diagram which shows the structure of the whole elevator system containing the elevator braking apparatus which concerns on Embodiment 2 of this invention.
7 is a configuration diagram showing a configuration of a brake device according to Embodiment 2 of the present invention.
8 is a configuration diagram showing a configuration of a brake device according to Embodiment 3 of the present invention.
FIG. 9: is a block diagram which shows the state which rotated the 1st rotation sliding part which concerns on Embodiment 3 of this invention upward, and rotated the 2nd rotation sliding part downward.
It is a block diagram which shows the structure of the brake apparatus which concerns on Embodiment 4 of this invention.
It is a block diagram which shows the state which rotated the rotating sliding part which concerns on Embodiment 4 of this invention upward.

Embodiment 1.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the structure of the whole elevator system provided with the elevator braking apparatus which concerns on Embodiment 1 of this invention. Hereinafter, the elevator braking device is referred to as a brake device 8.

In FIG. 1, the car 1 of an elevator is arrange | positioned in a hoistway. The hoisting machine 2 is provided in the upper part of the hoistway. A rope 3 is wound around the sheave provided in the hoist 2. A car 1 is provided at one end of the rope 3, and a counterweight 4 is provided at the other end of the rope 3. The car 1 and the counterweight 4 are suspended by a rope 3 like a roll. The car 1 is driven up and down by the motor provided in the hoist 2. In the hoistway, a pair of guide rails 5 for guiding the hoisting of the car 1 are provided. The guide rail 5 extends in the lifting direction of the car 1. In this embodiment, the guide rail 5 comprises the braking surface as a target. That is, the holding | maintenance and braking of the car 1 are performed by holding the guide rail 5 by the brake apparatus 8.

Lifting and lowering of the car 1 is controlled by the elevator control apparatus 6. The elevator control apparatus 6 is provided with the braking command part 7. The braking command unit 7 outputs a holding command for stopping and holding the car 1 when the car 1 stops on each floor and a braking command for braking the car 1 when an abnormality occurs in the elevator. .

The car 1 is mounted with a pair of brake devices 8. The brake device 8 is an elevator brake device that holds and brakes the car 1 by holding the guide rails 5. Each brake device 8 is controlled by the brake control device 9. The brake control device 9 receives the holding command or the braking command from the braking command unit 7 to operate the brake device 8. The brake control device 9 is provided with a control unit 10 for controlling the operation of the brake device 8 and a load detection unit 11 for detecting the load of the car 1.

FIG. 2 is a side view illustrating the configuration of the brake device 8 of FIG. 1. Although it is a side view rather than sectional drawing, in order to make a drawing clear, different coloring or hatching is performed for each member. This also applies to FIGS. 3 to 5 described later. 2, the lifting direction of the car 1 is called "Y-axis direction", and the direction perpendicular | vertical with respect to a Y-axis direction is called "X-axis direction" and "Z-axis direction". In addition, "X-axis direction" is the left-right direction of the paper, and "Z-axis direction" is the inner direction of the paper. This also applies to FIGS. 3 to 5 described later.

In FIG. 2, the mounting frame 12 is provided on the side of the car 1. The mounting frame 12 has a rectangular frame shape. The guide rod 13 is provided in the installation frame 12. The position where the guide rod 13 is provided is a position below the center in the installation frame 12. The guide rod 13 has a rod shape and extends in the X-axis direction.

The movable part 14 is provided in the installation frame 12. One or more protrusions are provided in the lower part of the movable part 14. The guide rod 13 penetrates through the protrusion part of the movable part 14. Thereby, the movable part 14 is slidable with respect to the installation frame 12 along the guide rod 13. That is, the movable part 14 is displaceable in the X-axis direction. As a result, the movable portion 14 is displaced with respect to the car 1 and the guide rail 5 in the vertical direction, that is, in the X-axis direction.

The movable part 14 is provided with the reception side sliding part 15 and the rotation sliding part 16. As shown in FIG. The reception side sliding part 15 and the rotation sliding part 16 oppose each other across the guide rail 5 in the X-axis direction. That is, the guide rail 5 is arrange | positioned between the reception side sliding part 15 and the rotation sliding part 16. As shown in FIG. The reception side sliding part 15 and the rotation sliding part 16 are displaced in the X-axis direction together with the movable part 14. And the reception side sliding part 15 and the rotation sliding part 16 are each connectable and removable with respect to the guide rail 5 according to the displacement of the movable part 14 with respect to the installation frame 12. As shown in FIG.

The receiving side sliding part 15 is provided with the braking shoe 17 in the surface which contacts the guide rail 5. The upper sliding shoe 18 and the lower brake shoe 19 are provided in the rotation sliding part 16.

The reception side sliding part 15 is fixed to the movable part 14. Although the reception side sliding part 15 may be comprised from a member different from the movable part 14, the reception side sliding part 15 may be integrally formed with the movable part 14.

On the other hand, the rotation sliding part 16 is provided with respect to the movable part 14 so that rotation is possible. The structure will be described below.

The rotation sliding part 16 is provided in the movable part 14 via the motor 20. As shown in FIG. The motor 20 is a first drive unit. The rotating shaft of the motor 20 is arrange | positioned in the Z-axis direction, and is provided in the movable part 14 and the rotation sliding part 16. As shown in FIG. The rotation sliding part 16 is able to rotate in the up-and-down direction about the rotating shaft of the motor 20. As shown in FIG. By energizing the motor 20, a rotational torque for rotating the rotational sliding portion 16 is generated. On the other hand, when the power supply of the motor 20 is cut off, rotational torque is lost, and the rotation sliding part 16 is free to rotate.

The outer peripheral part of the rotation sliding part 16 is divided roughly and is comprised by three sides. One side is a curve, and the other two sides are a straight line. The curved outer periphery of the rotating sliding part 16 is arrange | positioned at the guide rail 5 side. The curved outer periphery of the rotating sliding part 16 constitutes the contact surface which the guide rail 5 can contact. The contact surface is formed so that the radius of curvature from a rotation axis may become large with the increase of the rotation angle in a vertical direction from the center contact surface in the horizontal angle used as a reference | standard. The upper braking shoe 18 is arrange | positioned at the upper end of a contact surface, and the lower braking shoe 19 is arrange | positioned at the lower end of a contact surface.

Moreover, the 2nd drive part is provided in the installation frame 12. As shown in FIG. The 2nd drive part is comprised from the electromagnet 21 and the pressurized spring 22, for example. The lower part of the electromagnet 21 is provided with the projection part. The guide rod 13 penetrates the electromagnet 21. The electromagnet 21 is slidable with respect to the installation frame 12 along the guide rod 13. The pressurized spring 22 is provided between the movable part 14 and the electromagnet 21, and gives the force which isolate | separates the movable part 14 and the electromagnet 21. The electromagnet 21 draws the movable part 14 against the pressing force of the pressurized spring 22 by an electromagnetic force by flowing an electric current. On the other hand, when the feeding to the electromagnet 21 is stopped and the electromagnetic force of the electromagnet 21 is stopped, the electromagnet 21 is moved away from the movable portion 14 by the pressing force of the pressure spring 22. Go to.

In this embodiment, although the structure of the movable part 14, the electromagnet 21, and the pressurized spring 22 was demonstrated to the example, it is not limited to this, but the movable part 14, the split movable part, and the pressurized spring 22 are described. It is good also as a structure. In this embodiment, the electromagnet 21 is corresponded to a division movable part. The split movable portion is provided so as to be connectable and detachable from the movable portion 14, and the movable portion 14 and the divided movable portion are separated by the pressing force of the pressurized spring 22. In such a configuration, the electromagnet is not necessarily provided in the divided movable portion, and the electromagnet may be provided in the movable portion 14. At the time of energizing the power supply to the electromagnet, the split movable portion is drawn toward the movable portion 14 against the pressing force of the pressurized spring 22.

As a position adjustment part for holding the position of the movable part 14 in a brake release state, the position adjustment spring 23 is arrange | positioned between the electromagnet 21 and the installation frame 12. As shown in FIG. Since the mounting frame 12 is provided on the side surface of the car 1, the positioning spring 23 acts as a force acting between the electromagnet 21 and the car 1. Therefore, the position adjustment spring 23 may be arrange | positioned directly between the electromagnet 21 and the car 1. The position adjustment spring 23 is designed with a sufficiently small pressing force as compared with the pressurized spring 22. In addition, although the position adjustment spring 23 is used as a position adjustment part here, it is not limited to this, The mechanism which can acquire the restoring force, such as rubber | gum, can also be used. In addition, although the position adjustment spring 23 is arrange | positioned between the mounting frame 12 and the electromagnet 21 here, you may arrange | position between the mounting frame 12 and the movable part 14.

The mounting frame 12 is provided with a positioning mechanism (see numerals 24 and 25) for positioning the electromagnet 21. The positioning mechanism is disposed between the electromagnet 21 and the mounting frame 12. When the electromagnet 21 is separated from the movable part 14 by the pressing force of the pressurized spring 22, the positioning mechanism adjusts the position of the electromagnet 21 with respect to the installation frame 12 in the X-axis direction. In addition, in the example shown in FIG. 2, the positioning mechanism is comprised by the positioning bolt 24 and the plate 25. As shown in FIG. The plate 25 is disposed inside the mounting frame 12. The plate 25 has a flat plate shape. One main surface of the plate 25 opposes the electromagnet 21. The plate 25 is fixed to the mounting frame 12 by the position adjustment bolt 24. When the electromagnet 21 moves in the direction away from the movable part 14, the electromagnet 21 touches the plate 25 and stops. In addition, by providing a shock absorbing material such as rubber on the main surface of the plate 25 on the electromagnet 21 side, the impact when the electromagnet 21 collides with the plate 25 can be reduced.

The operation of the brake device 8 according to Embodiment 1 of the present invention will be described below. As the operation of the brake device 8, there are a normal operation in which the car 1 in a stopped state on each floor is stopped and an emergency operation in which the car 1 is braked when an abnormality occurs in the elevator.

First, the normal operation of the brake device 8 will be described. In normal operation, the car 1 is stopped at the stop position of each floor by the hoist 2 by the control of the elevator control device 6. Thereafter, the holding command for holding the car 1 is output from the braking command unit 7 of the elevator control device 6 to the control unit 10 of the brake control device 9. The control unit 10 obtains the magnitude of the load of the car 1 from the load detection unit 11 when receiving the maintenance instruction. Next, the control part 10 energizes the motor 20 according to the magnitude | size of the load of the car 1, generate | occur | produces a rotation torque to the rotation sliding part 16, and moves the rotation sliding part 16 upwards. Or rotate downward.

As the load detection unit 11, the load in the car 1 may be measured by the same as the scale device, and the motor torque necessary for stopping the car 1 by the motor of the hoisting machine 2 is estimated from the motor current, The load of the car 1 may be estimated from the weight of the counterweight 4.

Here, the case where the load of the car 1 is larger than the load by the counterweight 4 is demonstrated and the movement of the normal operation of the brake apparatus 8 of 1st Embodiment is demonstrated.

3 shows the brake device 8 when the pivot sliding portion 16 is rotated in the upward direction by the motor 20. When the load of the car 1 detected by the load detection part 11 is larger than the load by the counterweight 4, in other words, when there is no motor torque by the hoist 2, the car 1 will go down In the case of throwing away, the control unit 10 commands the motor 20 to rotate the rotation sliding unit 16 upward. "Up direction" here means the direction of the arrow of FIG. That is, it means a clockwise direction about the rotation axis of the motor 20. In addition, although the case where the car 1 descends downwards is demonstrated here as an example, when the car 1 raises up, the control part 10 rotates the rotation sliding part 16 to the downward direction. Command to the motor 20. That is, in that case, the rotation sliding part 16 is rotated counterclockwise centering on the rotating shaft of the motor 20.

As the rotational sliding portion 16 is rotated in the upward direction, due to the shape of the rotational sliding portion 16 described above, the gap between the rotational sliding portion 16 and the guide rail 5 is reduced, and the rotational sliding The part 16 is in contact with the guide rail 5. After that, when the rotational sliding portion 16 further rotates, the movable portion 14 is displaced in a direction in which the reception side sliding portion 15 approaches the guide rail 5. When the braking shoe 17 contacts the guide rail 5, the guide rail 5 is gripped between the braking shoe 17 and the lower braking shoe 19.

When the guide rail 5 is gripped, the control unit 10 stops the electromagnetic force of the electromagnet 21. 4 shows the brake device 8 when the electromagnetic force of the electromagnet 21 is stopped after the guide rail 5 is gripped. When the electromagnetic force of the electromagnet 21 disappears, the electromagnet 21 is displaced in the direction away from the movable part 14 by the pressing force of the pressurized spring 22, as shown by the arrow of FIG. To stop. After holding the guide rail 5, the energy consumption can be suppressed by stopping the electromagnet 21.

After holding the guide rail 5, the motor torque of the hoist 2 is stopped. When the motor torque is stopped, the load of the value obtained by subtracting the load by the counterweight 4 from the load by the car 1 acts downward on the car 1. The torque which tries to rotate the rotation sliding part 16 further by this load acts. The self-lifting function functions by the torque by the difference of the load of the car 1 and the counterweight 4, and the braking force acting on the guide rail 5 increases. Therefore, the torque applied to the motor 20 can be reduced, and a high braking force can be generated even with a small lightweight motor.

Finally, when the motor torque of the hoist 2 is stopped, the suspension holding of the car 1 is completed, so the elevator control device 6 opens the door of the car 1. In this way, the passengers get on and off. Since the load of the car 1 changes as the passenger gets on and off, the sign of the difference between the load of the car 1 and the load of the counterweight 4 may be reversed. When the load of the counterweight 4 becomes larger than the load of the car 1, the car 1 tries to move upward. Accordingly, due to the difference between the load of the car 1 and the load of the counterweight 4, the torque acting on the pivot sliding portion 16 acts in the direction of rotating the pivot sliding portion 16 downward. . The control unit 10 monitors the load information of the car 1 detected from the load detection unit 11 even during the getting on and off of the passenger, the load of the car 1 varies, and the load of the car 1 and the balance weight ( When the direction in which the difference of the load of 4) acts is reversed, the torque of the motor 20 is reversed, and the rotation sliding part 16 is rotated to the opposite side. During the getting on and off of the passenger, the load detection unit 11 may measure the load in the car 1 as the scale device, or the load of the car 1 and the load of the counterweight 4 using the encoder of the hoisting machine 2. The direction in which the difference between the two acts may be detected.

When the passengers get on and off, the elevator control device 6 closes the door of the car 1 and performs the opening operation of the brake device 8. The elevator control apparatus 6 first outputs the motor torque required for stopping the car 1 to the hoist 2 before the opening operation of the brake apparatus 8. Next, a command is given to the brake control device 9 to perform the opening operation of the brake device 8. The brake control apparatus 9 energizes the electromagnet 21 by the said instruction | command, and makes the movable part 14 adsorb | suck the electromagnet 21 by the electromagnetic force of the electromagnet 21. FIG. The magnitude of the electromagnetic force required to attract the electromagnet 21 to the movable portion 14 changes depending on the gap between the electromagnet 21 and the movable portion 14 in the state where the brake device 8 is operated. The gap between the electromagnet 21 and the movable portion 14 in the state where the brake device 8 is operable can be adjusted by the position adjusting bolt 24 of the positioning mechanism, and by adjusting the gap small, the electromagnet Since the electromagnetic force required to attract (21) can be made small, the electromagnet 21 can be made small.

After attracting the electromagnet 21 to the movable part 14 by the electromagnetic force of the electromagnet 21, the brake control apparatus 9 initializes the rotation sliding part 16 by the motor torque of the motor 20. FIG. Return to the horizontal angle of. That is, the rotation sliding part 16 is rotated so that the center contact surface of the rotation sliding part 16 may be a position which opposes the guide rail 5 so that it may become the state shown in FIG. As the angle of the rotation sliding part 16 returns horizontally, the movable part 14 returns to the initial position by the position adjustment spring 23. As shown in FIG. As a result, the receiving side sliding portion 15 is displaced in a direction away from the guide rail 5, the braking shoe 17 is away from the guide rail 5, and the gripping of the guide rail 5 is released.

The above is the movement of the normal operation of the brake device 8 of the first embodiment.

Next, the emergency operation of the brake device 8 will be described. Here, a case where any abnormality occurs during the lowering of the car 1 and the emergency operation of the brake device 8 is described will be described as an example. FIG. 5 shows the brake device 8 when the car 1 performs an emergency operation while descending.

If any abnormality occurs in the elevator, the braking command unit 7 outputs a braking command to the control unit 10. At this time, it is in the state of FIG. The control unit 10 interrupts the electric current of the electromagnet 21 and stops the electromagnetic force when the braking command is received. When the electromagnetic force of the electromagnet 21 is cut off, the movable part 14 and the electromagnet 21 are separated by the pressurized spring 22, and the electromagnet 21 comes into contact with the plate 25, and the rotating sliding part ( 16 is in contact with the guide rail (5). At the time of contact, the rotation sliding part 16 is not rotating yet, and is the state of an initial horizontal angle.

It is necessary to make the movable sliding part 16 contact with the guide rail 5 by separating the movable part 14 and the electromagnet 21 at the time of blocking the electric current of the electromagnet 21. Therefore, the pressing force of the position adjustment spring 23 when the electromagnet 21 is in contact with the plate 25 which is a positioning mechanism and stops interrupts the electric current of the electromagnet 21, and rotates 16 ) Is set to be smaller than the pressing force by the pressurized spring 22 acting between the movable portion 14 and the electromagnet 21 in a state of contacting the guide rail 5.

In this way, if the rotational sliding part 16 contacts the guide rail 5 during the lowering of the car 1, the rotational sliding part 16 will move with the guide rail 5 in accordance with the movement of the car 1, and so on. It is pulled by the friction force and rotates upwards. That is, it rotates clockwise. In accordance with the rotation of the rotary sliding portion 16 in the upward direction, the movable portion 14 is displaced in the X-axis direction in a direction in which the receiving side sliding portion 15 approaches the guide rail 5. When the braking shoe 17 contacts the guide rail 5, the guide rail 5 is gripped between the braking shoe 17 and the lower braking shoe 19. Thereby, a braking force acts on the car 1, and the car 1 decelerates to a stop state.

In addition, if the rotating sliding portion 16 contacts the guide rail 5 while the car 1 is being raised, the rotating sliding portion 16 moves downward, i.e., counterclockwise, as the car 1 moves. Rotate to

Also in the emergency operation, the magnetic backing action functions by the torque which tries to rotate the rotation sliding part 16 which arises by the movement of the car 1, and can generate a high braking force with respect to the car 1.

Thus, by having the motor 20 as a 1st drive part which can operate the rotation sliding part 16 for normal operation directly, even if there is no movement of the car 1 at the time of normal operation, it is a self-lifting effect. High braking force can be achieved. In other words, a high braking force can be realized while preventing the car 1 stopped on each floor from falling. In addition, apart from the first drive unit, having the second drive unit (electromagnet 21 and the pressurized spring 22) capable of operating the brake device 8 by turning off the power, even when an abnormality occurs in the elevator, The car 1 can be braked. In addition, in any of the up and down directions, by using the rotational sliding portion 16 whose radius of curvature from the rotational axis increases as the rotation angle increases, a high braking force due to the self-lifting force can be obtained in both the up and down directions. As a result, the brake device 8 can be miniaturized.

In addition, since the gap between the movable part 14 and the electromagnet 21 at the time of the operation | movement of the brake apparatus 8 by the positioning mechanism can be adjusted so that an electromagnet 21 can be made small and a brake apparatus ( 8) can be downsized.

In addition, the load detection unit 11 detects the load of the car 1 and changes the rotation direction of the rotation sliding part 16 according to the detected load size, thereby lowering the car 1 when the passenger rides. You can also stop.

As mentioned above, the elevator braking device which concerns on this embodiment can be rotated with respect to the movable part 14 and the movable part 14 which can be displaced in the perpendicular direction with respect to the guide rail 5 as a target braking surface. And a motor as a first driving part for rotating the rotating sliding part 16 and the rotating sliding part 16 arranged to contact the braking surface when rotated by a preset rotational angle from a horizontal angle as a reference ( 20) and the movable part 14 is displaced so that the rotating sliding part 16 may displace in the direction which contacts a braking surface at the time of a power interruption, and the rotating sliding part 16 in a horizontal angle state will be The electromagnet 21 and the pressurized spring 22 as a 2nd drive part which hold the movable part 14 so that it may become a position which does not contact a braking surface are provided. In the elevator braking device according to the present embodiment, the rotating sliding portion 16 is brought into contact with the braking surface by rotating the rotating sliding portion 16 by the first driving portion in the normal operation. Maintain hibernation. In an emergency, by turning off the electromagnet 21 of the second drive unit, the rotating sliding unit 16 is brought into contact with the braking surface to brake the braking surface. As a result, in normal times, a magnetic backing action can be obtained without moving the car 1, and braking can be reliably obtained even in abnormal times.

In addition, since the rotational sliding part 16 is comprised so that the curvature radius may become large with the increase of the rotation angle from a horizontal angle in both directions from a horizontal angle, in normal operation, it is previously made from the horizontal angle used as a reference | standard. It can be made to contact a braking surface when it rotates by the set rotation angle, and to not contact a braking surface in the state of a horizontal angle.

Moreover, the 1st drive part is comprised so that it may generate | generate the rotational torque which rotates the rotational sliding part 16 at the time of energization, and will lose | disappear the rotational torque at the time of power supply interruption. In addition, the second drive part is pressurized spring 22 which displaces the movable part 14 toward the direction in which the rotational sliding part 16 contacts a braking surface by the pressing force, and the pressing force of the pressurizing spring 22 by energization. It has an electromagnet 21 which sucks the movable part 14 back. As a result, braking can be reliably obtained by turning off the power supply in the event of abnormality.

Moreover, the position adjustment spring 23 as a position adjustment part which maintains the position of a movable part by the pressing force at the time of the power cut off of a 2nd drive part, and the position of the electromagnet 21 at the time of shutting off the power supply of the electromagnet 21 is maintained. The positioning bolt 24 and the plate 25 as a positioning mechanism are further provided. In addition, the pressing force of the position adjustment spring 23 which is a position adjustment part is smaller than the pressing force of the pressurized spring 22. As shown in FIG. Thereby, since a clearance gap can be produced | generated between a braking surface and the rotation sliding part 16 at the time of a brake release by a position adjustment part, drag operation can be avoided. In addition, since the electromagnetic force required for the electromagnet 21 is suppressed by the position adjusting unit, the electromagnet 21 can be miniaturized.

It further comprises a load detection unit 11 for detecting the load of the car 1, the first drive unit, the rotation of the rotary sliding unit 16 in accordance with the load of the car 1 detected by the load detection unit 11 To control. Thereby, the moving direction of the car 1 by the unbalanced torque which changes according to the load in the car 1 can be detected, and the rotation sliding part 16 can be rotated to an appropriate direction. In addition, it is possible to always obtain the self-lifting action.

Embodiment 2.

In the first embodiment described above, the case in which the elevator braking device is disposed in the car 1 has been described. However, the present invention is not limited thereto, and as shown in FIG. 6, even if the elevator braking device is disposed in the hoisting machine 2. good.

It is a block diagram which shows the structure of the whole elevator system in which the elevator braking apparatus which concerns on Embodiment 2 of this invention was provided. In this embodiment, as shown in FIG. 6, the elevator braking apparatus is arrange | positioned at the hoisting machine 2, and this point is different from above-mentioned Embodiment 1. In addition, about the thing similar to Embodiment 1 mentioned above, the same code | symbol as the above-mentioned is shown or "a" is attached after the same code | symbol, and detailed description is abbreviate | omitted here.

In FIG. 6, in the hoist 2, a brake drum 26 (see FIG. 7) is provided on the shaft that couples the sheave and the motor. The brake drum is generally a member used in the hoist 2. In the present embodiment, a pair of brake devices 8a are mounted on the hoisting machine 2. The brake device 8a is an elevator brake device that holds and brakes the car 1 using the brake drum 26. That is, in this embodiment, the brake drum 26 comprises the braking surface as an object. That is, by holding the brake drum 26 with the brake device 8a, the car 1 is held and braked.

FIG. 7: is a block diagram which shows the brake apparatus 8a of FIG. Although FIG. 7 is a side view rather than a sectional drawing, in order to make drawing clear, a different coloring or hatching is performed for each member. In addition, in FIG. 7, the lifting direction of the car 1 is called "Y-axis direction", and the direction perpendicular | vertical with respect to a Y-axis direction is called "X-axis direction" and "Z-axis direction". In addition, "X-axis direction" is the left-right direction of the paper, and "Z-axis direction" is the inner direction of the paper. In addition, although the installation frame 12 is not shown in FIG. 7, in fact, also in this embodiment, the installation frame 12 is provided similarly to Embodiment 1. In FIG.

In FIG. 7, the guide rod 13a is arrange | positioned perpendicularly with respect to the brake drum 26 which is a braking surface. That is, the braking surface of the brake drum 26 is arrange | positioned in the Y-axis direction, and the guide rod 13a is arrange | positioned in the X-axis direction. The projection part is provided below the movable part 14a. The guide rod 13a penetrates into the protrusion part of the movable part 14a. As a result, the movable portion 14a is slidable along the guide rod 13a in the X-axis direction. In other words, the movable portion 14a is displaceable with respect to the brake drum 26 in the vertical direction, that is, in the X-axis direction.

The rotating sliding part 16a is provided in the movable part 14a. The rotational sliding part 16a is displaced in the X-axis direction according to the displacement of the movable part 14a, and can be connected to and disconnected from the brake drum 26.

The upper brake shoe 18a and the lower brake shoe 19a are provided in the rotation sliding part 16a. The shape of the rotation sliding part 16a is the same as that of the rotation sliding part 16 shown in Embodiment 1 mentioned above.

The rotation sliding part 16a is provided in the movable part 14a via the motor 20a. The motor 20a is a 1st drive part. The rotating shaft of the motor 20a is provided in the movable part 14 and the rotation sliding part 16a. The rotating shaft of the motor 20a is arrange | positioned in the Z-axis direction. The rotating sliding part 16a is provided in the rotating shaft of the motor 20a. The rotation sliding part 16a is able to rotate in the up-and-down direction about the rotating shaft of the motor 20a. By energizing the motor 20a, a rotational torque for rotating the rotational sliding portion 16a is generated. On the other hand, when the power is cut off, the rotation torque is lost, and the rotation sliding portion 16a is free to rotate.

The outer periphery of the brake drum 26 side of the rotating sliding part 16a comprises the contact surface which the brake drum 26 can contact. The contact surface is formed such that the radius of curvature from the rotational axis increases as the rotation angle in the respective directions increases from the center contact surface. The upper braking shoe 18a is disposed at one end of the contact surface, and the lower braking shoe 19a is disposed at the other end of the contact surface.

Moreover, the electromagnet 21a and the pressurized spring 22a are provided as a 2nd drive part. A protrusion is provided below the electromagnet 21a. The guide rod 13a penetrates through the protrusion part of the electromagnet 21a. The electromagnet 21a is slidable in the X-axis direction with respect to the mounting frame 12 along the guide rod 13a. The pressurized spring 22a is provided between the movable part 14a and the electromagnet 21a, and gives the force which isolate | separates the movable part 14a and the electromagnet 21a. The electromagnet 21a draws a current and draws the movable part 14a against the pressing force of the pressurized spring 22a by an electromagnetic force. On the other hand, when the feeding to the electromagnet 21a is stopped and the electromagnetic force of the electromagnet 21a is stopped, the electromagnet 21a is moved away from the movable portion 14a by the pressing force of the pressure spring 22a. Go to. Moreover, you may use rubber instead of the pressurized spring 22a.

The operation of the brake device 8a according to Embodiment 2 of the present invention will be described below. First, the normal operation of the brake device 8a will be described. After the car 1 is stopped at the stop position of each floor by the hoist 2, from the brake command part 7 of the elevator control apparatus 6, with respect to the control part 10 of the brake control apparatus 9, The maintenance command is output. When the control unit 10 receives the holding instruction, the control unit 10 acquires the magnitude of the load of the car 1 from the load detection unit 11, energizes the motor 20a according to the load of the car 1, and rotates the sliding unit 16a. ), The rotational sliding portion 16a is rotated. The rotation direction of the rotation sliding part 16a at this time becomes a reverse direction with respect to the torque which acts on the hoist 2 by the difference of the load by the car 1, and the load by the counterweight 4.

As the rotational sliding portion 16a is rotated, the gap between the rotational sliding portion 16a and the brake drum 26 becomes smaller, and the upper braking shoe 18a or the lower braking shoe provided on the rotational sliding portion 16a. 19a contacts the brake drum 26. At this time, which of the upper braking shoes 18a and the lower braking shoes 19a is in contact with the brake drum 26 is determined by the rotational direction of the rotating sliding portion 16a. When the upper braking shoe 18a or the lower braking shoe 19a is in contact with the brake drum 26, a braking force is generated and the brake drum 26 is maintained.

When the brake drum 26 is held, the elevator control device 6 stops the motor torque of the hoist 2. When the motor torque is stopped, the load obtained by subtracting the load of the counterweight 4 from the load of the car 1 acts on the hoisting machine 2. The torque which tries to rotate the rotation sliding part 16 further by this load acts. The torque due to the difference between the load of the car 1 and the load of the counterweight 4 acts as a magnetic backing force, and the braking force acting on the brake drum 26 is increased. Therefore, the torque applied to the motor 20 can be reduced, and a high braking force can be generated even with a small lightweight motor.

When the brake drum 26 is maintained, the control unit 10 stops the electromagnetic force of the electromagnet 21a. The energy consumption can be suppressed by stopping the electromagnet 21a.

When the motor torque of the hoisting machine 2 is stopped, the suspension holding of the car 1 is completed, so that the car 1 opens the door and the passengers get on and off.

When the passengers get on and off, the door of the car 1 is closed and the brake device 8a is opened. First, the elevator control apparatus 6 outputs the motor torque required to stop and hold the car 1 to the hoist 2 before the opening operation of the brake apparatus 8a. And the control part 10 of the brake control apparatus 9 adsorb | sucks the electromagnet 21a to the movable part 14a by the electromagnetic force of the electromagnet 21a.

And the control part 10 of the brake control apparatus 9 returns the rotation sliding part 16a to an initial angle by the motor torque of the motor 20a. When the angle of the rotation sliding part 16a returns, the upper brake shoe 18a or the lower brake shoe 19a is moved away from the brake drum 26 and the holding of the brake drum 26 is released.

Next, the emergency operation of the brake device 8a will be described. If any abnormality occurs in the elevator while the car 1 is running, the braking command unit 7 outputs a braking command to the control unit 10. When the control unit 10 receives the braking command, the control unit 10 cuts off the current of the electromagnet 21a and stops the electromagnetic force. When the electromagnetic force of the electromagnet 21a is interrupted, the movable part 14a and the electromagnet 21a are separated by the pressurized spring 22a, and the rotation sliding part 16a contacts the brake drum 26. As shown in FIG.

If the rotating sliding portion 16a comes in contact with the brake drum 26 while the car 1 is traveling, the rotating sliding portion 16a is moved by the frictional force with the brake drum 26 as the car 1 moves. Rotate In accordance with the rotation of the rotational sliding portion 16a, the movable portion 14a is displaced in a direction closer to the electromagnet 21a. When the brake drum 26 and the upper braking shoe 18a or the lower braking shoe 19a are in contact with each other, the brake drum 26 is braked by the upper braking shoe 18a or the lower braking shoe 19a. Thereby, a braking force acts on the car 1, and the car 1 decelerates to a stop state.

Even in the emergency operation, the magnetic back force action functions by the torque which tries to rotate the rotation sliding part 16a which arises by the movement of the car 1, and can generate a high braking force with respect to the car 1.

In this way, even if the elevator braking device is arranged on the hoisting machine 2, even in the normal operation, even if there is no movement of the car 1, a high braking force due to the self-lifting force can be realized and an abnormality occurs in the elevator. In addition, the car 1 can be braked certainly.

As described above, the elevator braking device according to the present embodiment can be rotated with respect to the movable portion 14a and the movable portion 14a which can be displaced in the vertical direction with respect to the brake drum 26 serving as the target braking surface. A motor as a first driving part which rotates the rotating sliding portion 16a and the rotating sliding portion 16a, which are arranged to contact the braking surface when rotated by a predetermined rotational angle from a horizontal angle of reference. 20a) and the movable part 14a is displaced so that the rotation sliding part 16a may displace in the direction which contacts a brake surface at the time of a power interruption, and the rotation sliding part 16a in the state of a horizontal angle will be carried out at the time of energization. The electromagnet 21a and the pressurized spring 22a as a 2nd drive part which hold | maintain the movable part 14a so that it may become a position which does not contact a braking surface are provided. The elevator braking device according to the present embodiment causes the rotating sliding part 16a to come into contact with the braking surface by rotating the rotating sliding part 16a by the first driving part in the normal operation. Maintain hibernation. In an emergency, by turning off the electromagnet 21a of the 2nd drive part, the rotation sliding part 16a is made to contact a braking surface, and braking of a braking surface is performed. As a result, in normal times, a magnetic backing action can be obtained without moving the car 1, and braking can be reliably obtained even in abnormal times.

In addition, since the rotational sliding part 16a is comprised so that the curvature radius may become large with the increase of the rotation angle from a horizontal angle in both directions from a horizontal angle similarly to Embodiment 1, in normal operation, When it rotates by the rotation angle preset from the horizontal angle used as a reference | standard, it can contact a braking surface, and can be made not to contact a braking surface in the state of a horizontal angle.

Moreover, the motor 20a which is a 1st drive part is comprised so that the rotational torque which rotates the rotational sliding part 16a at the time of an electricity supply may be lost, and the rotational torque will be lost at the time of power supply interruption. Moreover, the 2nd drive part pressurizes the pressurizing spring 22a which displaces the movable part 14a toward the direction which the rotation sliding part 16a contacts with a braking surface by pressing force, and the pressing force of the pressurizing spring 22a by energization. It has the electromagnet 21a which attracts the movable part 14a back. As a result, braking can be reliably obtained by turning off the power supply in the event of abnormality.

In addition, as in the first embodiment, a load detector 11 for detecting the load of the car 1 is further provided, and the first drive unit is in accordance with the load of the car 1 detected by the load detector 11. , The rotation of the rotation sliding unit 16 is controlled. Thereby, the moving direction of the car 1 by the unbalanced torque which changes according to the load in the car 1 can be detected, and the rotation sliding part 16 can be rotated to an appropriate direction. In addition, it is possible to always obtain the self-lifting action.

Embodiment 3.

In the first embodiment, the case where one rotational sliding portion 16 is disposed on the movable portion 14 has been described. However, the present invention is not limited thereto, and as shown in FIG. 8, the movable portion 14b is rotated. You may arrange | position the auxiliary rotation sliding part 28b which assists the sliding part 16b.

FIG. 8: is a block diagram which shows the brake device 8b of the elevator brake system which concerns on Embodiment 3 of this invention. In this embodiment, as shown in FIG. 8, the auxiliary rotation sliding part 28b which assists the rotation sliding part 16b is arrange | positioned at the movable part 14b, and this point is the same as Embodiment 1 mentioned above. Different. In addition, about the thing similar to Embodiment 1 mentioned above, the same code | symbol as the above-mentioned is shown or "b" is attached after the same code | symbol, and detailed description is abbreviate | omitted here.

8, the lifting direction of the car 1 is called "Y-axis direction", and the direction perpendicular | vertical with respect to a Y-axis direction is called "X-axis direction" and "Z-axis direction". In addition, "X-axis direction" is the left-right direction of the paper, and "Z-axis direction" is the inner direction of the paper.

In FIG. 8, the movable part 14b is provided in the installation frame 12b. And the receiving side sliding part 15b, the rotation sliding part 16b, and the auxiliary rotation sliding part 28b are provided in the movable part 14b. Similar to the rotation sliding part 16b, the auxiliary rotation sliding part 28b opposes the reception side sliding part 15b with the guide rail 5 interposed in the X-axis direction. That is, the guide rail 5 is arrange | positioned between the reception side sliding part 15b and the auxiliary rotation sliding part 28b. The auxiliary rotation sliding part 28b, the reception side sliding part 15b, and the rotation sliding part 16b are displaced in the X-axis direction together with the movable part 14b. And the auxiliary rotation sliding part 28b, the reception side sliding part 15b, and the rotation sliding part 16b are respectively with respect to the guide rail 5 according to the displacement of the movable part 14b with respect to the installation frame 12b. It is possible to connect and disconnect.

The auxiliary rotation sliding part 28b is provided so that rotation is possible with respect to the movable part 14b. The structure will be described below.

The upper brake shoe 29b and the lower brake shoe 30b are provided in the auxiliary rotation sliding part 28b. The auxiliary rotation sliding part 28b is provided in the movable part 14b via the motor 31b. The motor 20b provided in the rotational sliding part 16b and the motor 31b provided in the auxiliary rotational sliding part 28b become a 1st drive part. The rotating shaft of the motor 31b is arrange | positioned in the Z-axis direction, and is provided in the movable part 14b and the auxiliary rotation sliding part 28b. The auxiliary rotation sliding part 28b is rotatable in both the up and down directions about the rotational axis of the motor 31b. By energizing the motor 31b, a rotational torque for rotating the auxiliary rotation sliding portion 28b is generated. On the other hand, when the power supply of the motor 31b is cut off, the rotation torque is lost, and the auxiliary rotation sliding portion 28b is free to rotate.

The outer peripheral part of the auxiliary rotation sliding part 28b is largely divided, and is comprised by three sides. One side is a curve, and the other two sides are a straight line. The curved outer circumferential portion of the auxiliary pivot sliding portion 28b is disposed on the guide rail 5 side. The curved outer circumferential portion of the auxiliary rotation sliding portion 28b constitutes a contact surface to which the guide rail 5 can contact. The contact surface is formed so that the radius of curvature from a rotation axis may become large with the increase of the rotation angle in the up-down direction from the center contact surface in the reference horizontal angle. The upper braking shoe 29b is arrange | positioned at the upper end of a contact surface, and the lower braking shoe 30b is arrange | positioned at the lower end of a contact surface.

Since the auxiliary rotation sliding part 28b assists the function of the rotation sliding part 16b, the external shape of the auxiliary rotation sliding part 28b is smaller than the rotation sliding part 16b. Moreover, the motor 31b which rotates the auxiliary rotation sliding part 28b is provided smaller than the motor 20b which rotates the rotation sliding part 16b.

Hereinafter, the operation of the brake device 8b according to Embodiment 3 of the present invention will be described. First, the normal operation of the brake device 8b will be described. After the car 1 is stopped at the stop position of each floor by the hoist 2, from the brake command part 7 of the elevator control apparatus 6, with respect to the control part 10 of the brake control apparatus 9, The maintenance command is output. When the control unit 10 receives the holding instruction, the control unit 10 acquires the magnitude of the load of the car 1 from the load detection unit 11, energizes the motor 20b according to the load of the car 1, and rotates the sliding unit 16b. ), A rotational torque is generated, and the rotation sliding part 16b is rotated upwards or downwards. At the same time, the control unit 10 also energizes the motor 31b according to the load of the car 1, generates a rotational torque in the auxiliary rotation sliding portion 28b, and moves the auxiliary rotation sliding portion 28b in the upward or downward direction. Rotate to

The rotation direction of the rotation sliding part 16b at this time becomes a reverse direction with respect to the force acting on a car by the difference of the load by the car 1, and the load by the counterweight 4. On the other hand, the rotation direction of the auxiliary rotation sliding part 28b becomes the same direction as the force acting on the car by the difference between the load by the car 1 and the load by the counterweight 4. In other words, considering the case where the load of the car 1 is larger than the load by the counterweight 4, the downward force acts on the car 1. In this case, the rotation direction of the rotation sliding part 16b is an up direction, and the rotation direction of the auxiliary rotation sliding part 28b is a downward direction.

FIG. 9 shows the brake device 8b when the rotating sliding part 16b is rotated in the upward direction. The " upward direction " herein means a clockwise direction around the rotational axis of the motor 20b.

As the rotating sliding part 16b is rotated, the clearance gap between the rotating sliding part 16b and the guide rail 5 becomes small, and the rotating sliding part 16b contacts the guide rail 5. Then, when the rotation sliding part 16b rotates further, the movable part 14b is displaced by the direction in which the receiving side sliding part 15b approaches the guide rail 5 by it. When the braking shoe 17b is in contact with the guide rail 5, the guide rail 5 is disposed between the braking shoe 17b and the upper braking shoe 18b or between the braking shoe 17b and the lower braking shoe 19b. It is held between.

At this time, the auxiliary rotation sliding portion 28b is rotated in the opposite direction to the rotation sliding portion 16b. As the auxiliary rotation sliding portion 28b is also rotated, the gap between the auxiliary rotation sliding portion 28b and the guide rail 5 becomes small, and the auxiliary rotation sliding portion 28b also contacts the guide rail 5. . The auxiliary pivoting sliding portion 28b is rotated to maintain contact with the guide rail 5 in accordance with the displacement of the movable portion 14b. For example, by rotating the auxiliary rotation sliding portion 28b with a rotation torque smaller than the rotation torque generated in the rotation sliding portion 16b, the contact with the guide rail 5 is prevented without disturbing the displacement of the movable portion 14b. It can be maintained. When the braking shoe 17b is in contact with the guide rail 5, the upper braking shoe 29b or the lower braking shoe 30b is in contact with the guide rail 5.

After gripping the guide rail 5, generation of the motor torque from the hoist 2 is stopped. When generation | occurrence | production of motor torque is stopped, the load by the difference of the load by car 1 and the load of a counterweight is acting on car 1. By this load, the torque which tries to rotate the rotation sliding part 16b further acts. The magnetic backing action functions by the torque by the difference between the load of the car 1 and the load of the counterweight, and the braking force acting on the guide rail 5 can be increased.

When generation | occurrence | production of the motor torque from the hoisting machine 2 is stopped and the suspension hold | maintenance of the car 1 is completed, the car 1 opens a door and a passenger gets on and off. Since the load of the car 1 changes as the passenger gets on and off, the direction in which the difference between the load of the car 1 and the load of the counterweight 4 acts may be reversed. When the direction of action of the difference between the load of the car 1 and the load of the counterweight 4 is reversed by the getting on and off of the passenger, the rotating sliding portion 16b is caused by the difference between the load by the car 1 and the load of the counterweight. The torque acting on the side acts in the direction of reducing the braking force by the rotating sliding portion 16b. On the other hand, the torque which acts on the auxiliary rotation sliding part 28b by the difference of the load by the inverted car 1 and the load of the counterweight, acts in the direction which further rotates the auxiliary rotation sliding part 28b. A magnetic backing action functions on the auxiliary pivot sliding portion 28b, and the braking force acting on the guide rail 5 can be increased. Therefore, the control part 10 monitors the load information of the car 1 detected from the load detection part 11 even while getting on and off of a passenger, and the difference of the load of the car 1 and the load of the counterweight 4 acts. When the direction is reversed, the torque of the motor 31b is increased, and the braking force by the auxiliary pivot sliding portion 28b is increased. Since the auxiliary rotation sliding part 28b has been kept in contact with the guide rail 5 before the direction in which the difference between the load of the car 1 and the load of the counterweight 4 acts is reversed, the car 1 The braking force for grasping the guide rail 5 is generated immediately after the direction in which the difference between the load of the load and the counterweight 4 acts is reversed. As a result, even when the direction in which the difference between the load of the car 1 and the load of the counterweight 4 acts by the passenger's getting on and off is reversed, the high braking force due to the self-power action without the movement of the car 1. Can be realized.

At this time, the rotation sliding portion 16b maintains the contact state with the guide rails 5, and in contrast, when the direction in which the difference between the load of the car 1 and the load of the counterweight 4 acts is reversed. The braking force acting on the guide rail 5 may be increased by reversing the direction of rotation, generating a braking force in the same direction as the auxiliary pivot sliding portion 28b.

When the passengers get on and off, the elevator control device 6 closes the door of the car 1 and performs the opening operation of the brake device 8b. First, the elevator control apparatus 6 outputs the motor torque required to stop and hold the car 1 to the hoist 2 before opening operation of the brake apparatus 8b. And the control part 10 of the brake control apparatus 9 returns the rotation sliding part 16b to an initial angle by the motor torque of the motor 20b. At the same time, the control unit 10 also returns the auxiliary rotation sliding part 28b to the initial angle by the motor torque of the motor 31b. When the angles of the rotational sliding part 16b and the auxiliary rotational sliding part 28b return, the rotational sliding part 16b and the auxiliary rotational sliding part 28b are guide rails 5 by the pressing force of the positioning spring 23b. Away from it, the grip of the guide rail 5 is released.

Next, the emergency operation of the brake device 8b will be described. If any abnormality occurs in the elevator while the car 1 is running, the braking command unit 7 outputs a braking command to the control unit 10. When the control unit 10 receives the control command, the control unit 10 cuts off the current of the electromagnet 21b and stops the electromagnetic force. When the electromagnetic force of the electromagnet 21b is interrupted, the movable part 14b and the electromagnet 21b are separated by the pressurized spring 22b, and the rotation sliding part 16b and the auxiliary rotation sliding part 28b are guide rails 5, respectively. ).

When the car 1 is traveling, and the rotation sliding part 16b and the auxiliary rotation sliding part 28b contact the guide rail 5, according to the movement of the car 1, the rotation sliding part 16b and the auxiliary rotation The sliding part 28b rotates by the frictional force with the guide rail 5. In accordance with the rotation of the rotational sliding portion 16b and the auxiliary rotational sliding portion 28b, the movable portion 14b is displaced in the direction in which the reception side sliding portion 15b approaches the guide rail 5. And when the braking shoe 17b contacts the guide rail 5, the guide rail 5 is between the braking shoe 17b, the upper braking shoe 18b, and the upper braking shoe 29b, or braking shoe 17b. ) And the lower braking shoe 19b and the lower braking shoe 30b. Thereby, a braking force acts on the car 1, and the car 1 decelerates to a stop state.

Even in the emergency stop, the self-lifting function functions by the torque which tries to rotate the rotational sliding part 16b and the auxiliary rotational sliding part 28b which generate | occur | produces by the movement of the car 1, and is high with respect to the car 1, and is high. It can generate braking force.

In addition, although the case where the rotating sliding part 16b and the auxiliary rotating sliding part 28b contact the guide rail 5 at the same time was demonstrated, it is not limited to this, The auxiliary rotating sliding part rather than the rotating sliding part 16b was demonstrated. 28b is arrange | positioned in the position away from the guide rail 5, and only the rotating sliding part 16b may contact the guide rail 5 at the time of emergency stop. On the contrary, only the auxiliary rotation sliding portion 28b may be arranged to be in contact with the guide rail 5 at the time of emergency stop.

As mentioned above, the elevator braking device which concerns on this embodiment is equipped with the auxiliary rotation sliding part 28b, and rotates in the opposite direction to the rotation sliding part 16b at the time of normal operation, and guides during passengers getting on and off. The contact state of the rail 5 and the upper brake shoe 29b or the lower brake shoe 30b is maintained. Thereby, even if the direction in which the difference between the load of the car 1 and the load of the counterweight acts changes, the guide rail 5 is immediately connected by the upper braking shoe 29b or the lower braking shoe 30b which is in contact. Can apply braking force. As a result, the movement of the car 1 can be prevented.

In addition, similarly to the first embodiment, in the normal operation, the braking surface is maintained by rotating the rotation sliding portion 16b by the motor 20b which is the first driving portion. Self-powering action can be obtained without moving 1).

Similarly to the rotation sliding portion 16b, the auxiliary rotation sliding portion 28b is also magnetized in any of the up and down directions by using a shape in which the radius of curvature from the rotation axis increases in accordance with the increase in the rotation angle. Since a high braking force due to the back force action can be obtained, the brake device 8b can be miniaturized.

In addition, in this embodiment, although the auxiliary rotation sliding part 28b was made smaller than the rotation sliding part 16b, it is not limited to this, The auxiliary rotation sliding part 28b and the rotation sliding part 16b are not limited to this. It may be the same size.

In addition, in this embodiment, although the reference | standard of the rotating sliding part 16b and the auxiliary rotating sliding part 28b is made into the horizontal angle, it is not limited to this, The predetermined angle tilt angle from the horizontal angle is referred to as a reference angle. It may be set as. The braking surface may be contacted when rotated by a predetermined rotational angle from the set reference angle, and may not be in contact with the braking surface in the state of the reference angle.

Embodiment 4.

In the first embodiment, the case of the rotating sliding portion 16 having a curved outer peripheral portion has been described. However, the present invention is not limited to this, and as shown in FIG. 10, the rotating sliding portion having an inclined outer peripheral portion ( 34c) may be arranged.

FIG. 10: is a block diagram which shows the brake device 8c of the elevator braking device which concerns on 4th Embodiment. In this embodiment, as shown in FIG. 10, the rotating sliding part 34c which has the inclined outer peripheral part is arrange | positioned, and this point differs from Embodiment 1 mentioned above. In addition, about the thing similar to Embodiment 1 mentioned above, the same code | symbol as the above-mentioned is shown, or "c" is shown after the same code | symbol, and detailed description is abbreviate | omitted here.

10, the lifting direction of the car 1 is called "Y-axis direction", and the direction perpendicular | vertical with respect to a Y-axis direction is called "X-axis direction" and "Z-axis direction". In addition, "X-axis direction" is the left-right direction of the paper, and "Z-axis direction" is the inner direction of the paper.

In FIG. 10, the movable part 14c is provided in the installation frame 12c. And the rotational sliding part 34c is provided in the movable part 14c. The rotating sliding part 34c is displaced in the X-axis direction together with the movable part 14c. And the rotation sliding part 34c is connectable with and disconnectable from the guide rail 5 according to the displacement of the movable part 14c with respect to the installation frame 12c.

Moreover, the reception side sliding part 36c is also provided in the installation frame 12c. The rotating sliding part 34c opposes the reception side sliding part 36c with the guide rail 5 interposed in the X-axis direction. That is, the guide rail 5 is arrange | positioned between the rotation sliding part 34c and the reception side sliding part 36c.

The reception side sliding part 36c has a U-shape. The reception side sliding part 36c is opened toward the direction of the movable part 14c in the X-axis direction. Specifically, the reception side sliding portion 36c is composed of a rod-shaped main body 36cc and a projection 36ca extending toward the pivot sliding portion 34c in the X-axis direction from both ends of the main body 36cc. have. The braking shoe 17c is provided in the surface which opposes the guide rail 5 of the main body 36cc of the reception side sliding part 36c, with the pressurized spring 32c interposed.

The cross-sectional shape of the front end part 34cc of the rotating sliding part 34c has triangles, such as an equilateral triangle or an isosceles triangle. The rotating sliding part 34c is arrange | positioned so that one side of the said triangle of the front end part 34cc, ie, one surface of the front end part 34cc, may be parallel with respect to the guide rail 5. The brake shoe 35c is provided in the surface of the front-end | tip part 34cc of the rotation sliding part 34c.

At least one projection 36cb is provided below the reception side sliding part 36c. The guide rod 13c penetrates through the projection part 36cb of the reception side sliding part 36c. Thereby, the reception side sliding part 36c is slidable with respect to the installation frame 12c along the guide rod 13c. That is, the reception side sliding part 36c is displaceable in the X-axis direction. As a result, the reception side sliding part 36c is displaced with respect to the car 1 and the guide rail 5 in the vertical direction, that is, in the X-axis direction. Moreover, as a position adjustment part for maintaining the position of the reception side sliding part 36c in a braking release state, the position adjustment spring 33c is arrange | positioned between the reception side sliding part 36c and the installation frame 12c. It is.

The rotating sliding part 34c is provided so that rotation is possible with respect to the movable part 14c.

Below, the structures of the rotation sliding part 34c and the reception side sliding part 36c are demonstrated.

The rotating sliding part 34c is provided in the movable part 14c via the motor 20c. The motor 20c is a 1st drive part. The rotating shaft of the motor 20c is arrange | positioned in the Z-axis direction, and is provided in the movable part 14c and the rotational sliding part 34c. The rotating sliding part 34c can be rotated in the up-and-down direction about the rotating shaft of the motor 20c. By energizing the motor 20c, a rotational torque for rotating the rotational sliding portion 34c is generated. On the other hand, when the power supply of the motor 20c is cut off, rotational torque is lost, and the rotation sliding part 34c is free to rotate.

As mentioned above, the braking shoe 35c is arrange | positioned at the surface which contacts the guide rail 5 of the front end part 34cc of the rotation sliding part 34c. Since the tip portion 34cc has a triangular cross-sectional shape, the opposite side of the surface on which the brake shoe 35c is provided is inclined in the vertical direction at the tip portion 34cc. Hereinafter, this part is called the inclined part of the tip part 34cc. The front end part 34cc of the rotation sliding part 34c is freely rotated with respect to the rotation sliding part 34c.

As mentioned above, the reception side sliding part 36c has a U-shape, and two projection parts 36ca are provided toward the rotation sliding part 34c. Those protruding portions 36ca of the rotary sliding portion 34c extend beyond the rear of the guide rail 5 to the rear of the tip portion 34cc of the rotary sliding portion 34c. And the tip of these protrusion part 36ca is inclined so as to oppose the inclination of the tip part 34cc of the rotation sliding part 34c, respectively. Specifically, the inclination of the inclined portion 36ca provided on the upper side and the upper half of the inclined portion of the tip portion 34cc face each other. do. Thus, the projection part 36ca of the reception side sliding part 36c also inclines in both the up-down direction like the tip part 34cc of the rotation sliding part 34c. Hereinafter, such a part is called the inclination part of the protrusion part 36ca.

The operation of the brake device 8c according to Embodiment 4 of the present invention will be described below. First, the normal operation of the brake device 8c will be described. After the car 1 is stopped at the stop position of each floor by the hoist 2, from the brake command part 7 of the elevator control apparatus 6, with respect to the control part 10 of the brake control apparatus 9, The maintenance command is output. When the control unit 10 receives the holding instruction, the control unit 10 acquires the magnitude of the load of the car 1 from the load detection unit 11, energizes the motor 20c according to the load of the car 1, and rotates the sliding unit 34c. ), The rotational sliding part 34c is rotated upward or downward.

The rotation direction of the rotation sliding part 34c at this time becomes a reverse direction with respect to the force acting on a car by the difference of the load by the car 1, and the load by the counterweight 4. In other words, considering the case where the load of the car 1 is larger than the load by the counterweight 4, the downward force acts on the car 1. In this case, the rotation direction of the rotation sliding part 34c becomes an upward direction.

FIG. 11 shows the brake device 8c when the rotating sliding part 34c is rotated in the upward direction. "Up direction" here means the clockwise direction centering on the rotating shaft of the motor 20c.

As the rotation sliding part 34c is rotated, the clearance gap between the rotation sliding part 34c and the reception side sliding part 36c becomes small, and the inclination part of the front end part 34cc of the rotation sliding part 34c rotates. It contacts the inclined part of the protrusion part 36ca of the sliding part 34c. After that, when the rotating sliding part 34c rotates further, the receiving side sliding part 36c is displaced in the direction which approaches the guide rail 5 by it. And the braking shoe 17c contacts the guide rail 5, and is pressed by the guide rail 5 via the pressure spring 32c. If the rotation sliding part 34c further rotates from that, the rotation sliding part 34c will make the inclination part of the tip part 34cc of the rotation sliding part 34c ride the inclination part of the protrusion part 36ca of the reception side sliding part 36c. ) Is displaced in a direction approaching the guide rail 5. At this time, the movable part 14c also displaces in the direction approaching the guide rail 5 by the rotational sliding part 34c. And when the brake shoe 35c provided in the rotational sliding part 34c contacts the guide rail 5, the guide rail 5 is gripped between the brake shoe 17c and the brake shoe 35c.

After gripping the guide rail 5, generation of the motor torque from the hoist 2 is stopped. When generation | occurrence | production of motor torque is stopped, the load by the difference of the load by car 1 and the load of a counterweight is acting on car 1. Since the mounting frame 12c installed in the car 1 is also subjected to the load in the direction moving in the same direction as the car 1 by this load, the load on the receiving side sliding portion 36c is applied upward or downward. All. At this time, since the inclined portion of the protrusion 36ca of the reception side sliding portion 36c and the inclined portion of the tip portion 34cc of the rotation sliding portion 34c are in contact with each other, the car 1 applied to the reception side sliding portion 36c is applied. The load due to the difference between the load due to the load and the balance weight and the inclined portion of the protrusion 36ca of the reception side sliding part 36c attempts to further push the pivot sliding part 34c to the guide rail 5. Act in the direction. By the load by the difference between the load of the car 1 and the load of the counterweight, the self-lifting function can function, and the braking force acting on the guide rail 5 can be increased. Therefore, the torque applied to the motor 20c can be reduced, and a high braking force can be generated even by a small and lightweight motor.

When the generation of the motor torque of the hoisting machine 2 is stopped, the stop holding of the car 1 is completed, so that the car 1 opens the door and the passengers get on and off.

When the passengers get on and off, the door of the car 1 is closed and the brake device 8c is opened. First, the elevator control apparatus 6 outputs the motor torque required for stopping the car 1 to the hoist 2 before the opening operation of the brake apparatus 8c. And the control part 10 of the brake control apparatus 9 returns the rotation sliding part 34c to an initial angle by the motor torque of the motor 20c. When the angle of the rotational sliding part 34c returns, the rotational sliding part 34c is moved away from the guide rail 5 by the pressing force of the positioning spring 23c, and is received by the pressing force of the positioning spring 33c. The sliding part 36c also moves away from the guide rail 5. As a result, the grip of the guide rail 5 is released.

Next, the emergency operation of the brake device 8c will be described. If any abnormality occurs in the elevator while the car 1 is running, the braking command unit 7 outputs a braking command to the control unit 10. When the control unit 10 receives the control command, the control unit 10 cuts off the current of the electromagnet 21c and stops the electromagnetic force. When the electromagnetic force of the electromagnet 21c is interrupted, the movable part 14c and the electromagnet 21c are separated by the pressurized spring 22c, and the rotation sliding part 34c contacts the guide rail 5.

If the car sliding part 34c contacts the guide rail 5 while the car 1 is traveling, it will rotate with the inclination part of the protrusion part 36ca of the reception side sliding part 36c as the car 1 moves. The inclined portion of the tip portion 34cc of the sliding portion 34c contacts. And the reception side sliding part 36c is displaced by the inclination part of the front end part 34cc of the rotation sliding part 34c in the direction from which the braking shoe 17c approaches the guide rail 5. And when the brake shoe 17c contacts the guide rail 5, the guide rail 5 is gripped between the brake shoe 17c and the brake shoe 35c. Thereby, a braking force acts on the car 1, and the car 1 decelerates to a stop state.

Even at the time of emergency stop, the rotation sliding part 34c applied to the rotation sliding part 34c from the inclination part of the protrusion part 36ca of the reception side sliding part 36c by the movement of the car 1 is guide rail ( By the load which tries to press 5), a magnetic back force action | function can function and it can generate a high braking force with respect to the car 1.

As mentioned above, the elevator braking apparatus which concerns on this embodiment is equipped with the rotating sliding part 34c which has a slope part, and the reception side sliding part 36c. As a result, a high braking force due to the self-lifting force can be obtained by the load caused by the difference between the load by the car 1 acting on the car 1 and the load of the counterweight, thereby miniaturizing the brake device 8c. can do.

In addition, similarly to the first embodiment, in the normal operation, the brake sliding surface is held by rotating the pivot sliding portion 34c by the motor 20c which is the first drive portion. Self-powering action can be obtained without moving 1).

1: car
2: hoisting machine
3: rope
4: Balance weight
5: guide rail
6: elevator control device
7: braking command
8, 8a, 8b, 8c: brake device
9: brake control device
10: control unit
11: load detector
12, 12b, 12c: mounting frame
13, 13a, 13b, 13c: guide rod
14, 14a, 14b, 14c: movable part
15, 15b: receiving side sliding part
16, 16a, 16b: rotating sliding part
17, 17b, 17c: braking shoe
18, 18a, 18b: upper braking shoe
19, 19a, 19b: lower braking shoe
20, 20a, 20b, 20c: motor
21, 21a, 21b, 21c: electromagnet
22, 22a, 22b, 22c: pressurized spring
23, 23b, 23c: position adjustment spring
24, 24b, 24c: positioning bolt
25, 25b, 25c: plate
26: brake drum
28b: auxiliary rotating sliding part
29b: Upper braking shoe
30b: lower braking shoe
31b: motor
32c: pressurized spring
33c: positioning spring
34c: rotating sliding part
35c: braking shoe
36c: sliding part of reception side

Claims (8)

A movable part which can be displaced in the vertical direction with respect to the target braking surface,
A rotational sliding portion provided so as to be rotatable with respect to the movable portion and arranged to contact the braking surface when rotated by a preset rotational angle from a reference angle as a reference;
A first drive unit which rotates the pivot sliding part with respect to the movable part;
The first sliding force generates a first pressing force for displacing the movable portion in a direction in which the rotating sliding portion contacts the braking surface, and when the power is energized, the movable portion moves in a direction in which the rotating sliding portion contacts the braking surface against the first pressing force. A second drive unit exerting a force that does not displace,
A position adjusting portion for generating a second pressing force for holding the movable portion at a position where the pivoting sliding portion in the state of the reference angle does not contact the braking surface when the second driving portion is energized;
Elevator braking device having a.
The method of claim 1,
An elevator braking device, wherein the magnitude of the second pressing force is smaller than the magnitude of the first pressing force. The method according to claim 1 or 2,
A split movable part provided to be connectable and detachable with respect to the movable part,
The second drive unit separates the movable unit and the divided movable unit when the power is cut off by the first pressing force, and connects the movable unit and the divided movable unit at the time of power supply.
Elevator braking system.
The method of claim 3, wherein
An elevator braking device, wherein the second pressing force acts between the split movable portion and the car of the elevator.
The method according to claim 1 or 2,
The second drive unit,
A pressurized spring for displacing the movable portion toward a direction in which the pivot sliding portion contacts the braking surface by the first pressing force;
Electromagnet which sucks the said movable part against the said 1st pressing force by the said pressurized spring by energization.
Having
Elevator braking system.
The method of claim 3, wherein
An elevator braking device, further comprising a positioning unit for maintaining the position of the split movable part when the power supply of the second driving unit is cut off.
The method according to claim 1 or 2,
The said rotation sliding part is an elevator braking apparatus comprised so that the radius of curvature of the surface which contacts the said braking surface may become large with the increase of the rotation angle from the said reference angle in both directions from the said reference angle.
The method according to claim 1 or 2,
Further provided with a load detection unit for detecting the load of the car,
The first drive unit controls the rotation of the rotation sliding unit in accordance with the load of the car detected by the load detection unit.
Elevator braking system.

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