EP2714565B1 - Controllable lift brake - Google Patents

Description

The invention relates to a method for controlling an elevator brake with a housing and an axially movable on a path between a braking position and a starting position operatively connected to at least one tractor unit brake unit, which brake unit is moved at least by means of a first spring force of at least one brake spring.

Elevator brakes must respond quickly on the one hand in an emergency and shut down the elevator car and the counterweight immediately, on the other hand, the elevator brakes must work as quietly as possible, so that the resulting noise in response to the elevator brake in the adjoining the elevator system rooms do not interfere. Known elevator brakes have at least one brake force generating spring or brake spring, wherein an electromagnetic device operates with at least one electromagnetic coil against the spring force while holding the brake, inter alia, in a starting position. When the voltage on the coil is turned off, the magnetic field collapses and the one brake unit of the elevator brake presses due to the spring force of at least one brake spring against, for example, a brake disc, elevator rail, etc. The brake unit is accelerated under the action of the spring force of the brake spring and presses against the brake disc for achieving a braking effect. Mostly press the brake unit from one side and another brake unit from the opposite side against the brake disc, such as from the WO 97/42118 is known.

A method and apparatus for controlling an elevator brake according to the preambles of claims 1 and 10 are known from EP1733992 A1 known.

In the event of an emergency, it may be necessary for an elevator car of the elevator installation to be moved to an evacuation floor, for example to evacuate persons trapped in the elevator car. To do this, the elevator brake must be released. However, if there is no power supply available to the elevator system, the elevator brake can not be released without the subsequent crash of the elevator car. In order to prevent a crash of the elevator car, the elevator brake must be controllable, so that the elevator car can be moved safely in an emergency, for example, to an evacuation floor.

But even during normal operation of the elevator system, it may make sense that the elevator brake is adjustable, for example for gentler braking.

An object of the invention is to propose a simple and efficient way of controlling an elevator brake.

The invention is solved by the features of the independent claims. Continuations are given in the dependent claims.

A core of the invention is that for controlling or regulating an elevator brake by means of a stroke generating lifting unit on a train unit of a brake unit, a movement in the axial direction against a first spring force of at least one brake spring is generated, wherein by means of a second spring force through the stroke the lifting unit tensioned compensating spring, the first spring force of the at least one brake spring is reduced.

The elevator brake has at least one housing and a brake unit movable in the axial direction on a path between a braking position and a starting position. Furthermore, the elevator brake has at least one brake spring which is in operative connection with the movable brake unit and which can be arranged in the housing. The at least one brake spring exerts a first spring force on the movable brake unit. The movable brake unit is in operative connection with a tractor unit. The at least one traction unit and the brake unit are either formed in one piece or by means of suitable means, for. As screws, by welding, by gluing, by means of a rope or the like, etc., connected together. The traction unit of the brake unit can be arranged so that it protrudes through the housing of the elevator brake, wherein it can be centered, decentered, symmetrical, asymmetric, etc. arranged through the housing of the elevator brake. It is also conceivable that the tractor unit is arranged in a suitable construction outside the housing of the elevator brake. The tractor can z. As a rod made of metal, a rope, a wire rope, etc.

In principle, any unit which can generate a stroke in the axial direction can be used as the lifting unit. Ideally, a non-self-locking lifting unit is used. For example, one could Kugelkalotteneinheit, a trapezoidal threaded unit, a non-self-locking thread, a spindle unit, etc. are used as a lifting unit. By means of the lifting unit, the brake unit with the tractor unit is moved in the axial direction counter to the first spring force of the at least one brake spring. By the second spring force of the at least one compensating spring, which are located in or close to the lifting unit or can be arranged, the amount of the first spring force of the at least one brake spring is reduced by the amount of the second spring force of the compensating spring.

The movement of the lifting unit and thus the axial movement of the brake unit can be carried out by means of at least one actuator connected to the lifting unit. However, the actuator can also be integrated in the lifting unit. In this case, as at least one actuator, a manually operated lever, a motor spindle unit, a spindle unit, a motor, a hydraulic unit, a solenoid, etc. may be used. According to the invention, the at least one actuator can be controlled or regulated via a control unit connected to the at least one actuator. Thus, it is possible that the stroke of the lifting unit is controlled or controlled via the at least one actuator by means of the control unit. The control unit may, for example, be an elevator control unit which is connected to the at least one actuator via a suitable communication network, whether wired or non-wired. Of course, the control unit could also represent a separate unit. The control unit can by means of analysis or evaluation or comparison of received data or parameters, for example position, speed, acceleration data, etc., which are transmitted from at least one sensor unit to the control unit via a communication network, the hub of the lifting unit on the regulate or control at least one actuator. Thus, it is possible that the elevator brake can be controlled or controlled. As a sensor unit in an elevator installation, any unit can be used which can provide the data or parameters necessary for the regulation or control of the elevator brake. As the sensor unit, for example, an acceleration sensor, an incremental encoder, an incremental motor, a position sensor, a speed sensor, etc. may be considered.

Frequently, an elevator brake has at least one electromagnetic coil, wherein the at least one electromagnetic coil can be arranged in the housing. The electromagnetic coil is used to hold the brake unit in a starting position. In the initial position of the elevator brake is no Braking effect. An additional possibility for reducing the first spring force of the at least one brake spring in the method according to the invention can be achieved by using an electromagnetic force of the at least one electromagnetic coil in addition to the second spring force of the compensating spring. The at least one electromagnetic coil could also be used to completely vent the elevator brake, ie, the magnetic force F _M , either with or without the second spring force F _{AF, is} greater than the first spring force F _BF , the at least one brake spring BF, and those therefrom resulting force is F _N = 0. Thus, the first spring force F _{BF is} canceled either with or without the second spring force F _AF by the magnetic force F _M. A ventilation of the elevator brake thus means that the brake unit does not cause any braking effect and, for example, no longer has any contact with the brake disk with the brake pad.

Both the stroke of the lifting unit via the actuator and the magnetic force of the at least one electromagnetic coil can be controlled or regulated or varied by the control unit.

An advantage of the invention is that the first spring force of the at least one brake spring can be controlled by acting on the brake unit lifting unit and the compensating spring and thus z. B. a safe way for controlled movement or for controlled lowering of an elevator car to an evacuation floor in an emergency are offered.

Another advantage of the invention is that, in an emergency stop of the elevator car due to the inventive method, a smoother braking without violation of safety standards can be performed.

Fig. 1

eine Aufzugsbremse in einer Bremslage,

Fig. 2

die Aufzugsbremse in einer geregelten Bremslage,

Fig. 3

die Aufzugsbremse in einer Ausgangslage,

Fig. 4a

eine Draufsicht auf eine beispielhafte Kugelkalotteneinheit,

Fig. 4b

einen Querschnitt durch die beispielhafte Kugelkalotteneinheit in einer Ausgangslage,

Fig. 4c

einen Querschnitt durch die beispielhafte Kugelkalotteneinheit in einer Hublage,

Fig. 5

ein Bremsdiagramm der erfindungsgemässen Aufzugszugsbremse,

Fig. 6a

ein weiteres Beispiel einer Aufzugsbremse,

Fig. 6b

einen Schnitt durch die z-y-Ebene des weiteren Beispiels einer Aufzugsbremse und

Fig. 7

ein Steuerungssystem für eine geregelte Aufzugsbremse.

The invention will be explained in more detail with reference to an embodiment shown in FIGS. Show

Fig. 1

an elevator brake in a braking position,

Fig. 2

the elevator brake in a controlled braking position,

Fig. 3

the elevator brake in a starting position,

Fig. 4a

a top view of an exemplary Kugelkalotteneinheit,

Fig. 4b

a cross section through the exemplary Kugelkalotteneinheit in a starting position,

Fig. 4c

a cross section through the exemplary Kugelkalotteneinheit in a stroke position,

Fig. 5

a brake diagram of the elevator brake according to the invention,

Fig. 6a

another example of an elevator brake,

Fig. 6b

a section through the zy plane of another example of an elevator brake and

Fig. 7

a control system for a controlled elevator brake.

FIG. 1 shows an example of an elevator brake in a braking position. In this example, the elevator brake has a housing 4, in which at least two brake springs BF are arranged for generating a first spring force F _BF , and a brake unit 3, which is movable in the axial direction, with a brake pad 2. The brake pad 2 presses in the braking position due to the first spring force F _BF of at least two brake springs BF against a brake disc 1. On the opposite side of the brake unit 3 with the brake pad 2 presses a further brake unit 9 with a brake pad 2 against the brake disc 1. This is For example, it is possible to brake an elevator car (not shown) of an elevator installation, for example in an emergency.

The brake unit 3 is in operative connection with a tractor unit 6 and in this example is firmly connected to the tractor unit 6. The brake unit 3 and the tractor unit 6 can be formed in one piece, for example, by casting, milling, punching, etc. or by suitable means, such as by screws, gluing, welding, etc., be joined together. In this example, the tractor unit 6 is rod-shaped and can be made of plastic, metal, ceramic, etc. The tractor 6 can protrude through the housing 4 centered or centered. Subsequently, a lifting unit 5 is arranged on the housing 4.

The lifting unit 5 is in operative connection with the tractor unit 6. Thus, it can be arranged on or on the tractor unit 6, as in this example, so that a movement in the axial direction of the tractor unit 6 and thus the brake unit 3 can be generated , The movement of the brake unit 3 or the tractor unit 6 is generated by the lifting unit 5 generating a stroke or a movement in the axial direction. How this hub is generated depends on the lifting unit 5 used. Thus, for example, as a lifting unit 5 a Kugelkalotteneinheit, a hydraulic cylinder, a spindle unit, a trapezoidal threaded unit, etc. can be used. The lifting unit has for generating the stroke to at least one Huberzeugungseinheit 5.1. The Huberzeugungseinheit 5.1 may be a spindle unit, at least one spherical cap, as shown in FIG. 4 is described, a screw unit, etc. be. Also, the lifting unit 5, the traction unit 6 enclose and be firmly connected to the tractor unit 6. In this example, as a lifting unit 5 a Kugelkalotteneinheit with balls 7 made of steel, plastic, ceramic, etc. used for generating a movement in the axial direction of the brake unit 3 and the tractor unit 6. Movement in the axial direction is understood to mean a movement along the x-axis in a Cartesian coordinate system. Of course, it is conceivable according to the invention that the lifting unit 5 also generates a movement of the brake unit 3 or the tractor unit 6 in any spatial direction (x, y, z - coordinates in a Cartesian coordinate system).

Due to the generated movement or the generated stroke of the lifting unit 5, a compensating spring AF is stretched. For this purpose, the compensating spring AF is in operative connection with the lifting unit 5. The compensating spring AF can, as shown in this embodiment, be arranged behind the lifting unit 5 on the traction unit 6. For this purpose, the traction unit 6 has a closure 13, so that the compensating spring AF can be tensioned. It is also conceivable that the compensating spring AF is integrated in the lifting unit 5 or in another unit of the elevator brake, for example in the brake unit 3, in an actuator 8, etc. Also, it could (AF) be arranged as a separate unit in the housing of the elevator brake.

The generation of the stroke or the movement in the lifting unit 5 is usually done by an actuator 8. Thus, the braking force, which is generated by the first spring force F _{BF of} the at least one brake spring BF, controlled or regulated by means of the movement of the lifting unit 5 , The actuator 8 may be a manual lever, but it is also conceivable that as the actuator 8, a motor spindle unit, a motor, a solenoid, a hydraulic unit, etc. are used. The control or regulation of the movement of the actuator 8 can take place with the aid of a control unit connected to the actuator 8, not shown in this example. For this purpose, the actuator 8 is connected to the control unit via a suitable communication network, for example a line-bound or line-unbound communication network, a radio communication network, etc. As a control unit, for example, an elevator control unit of an elevator installation or a separate unit can be used.

In this example, the elevator brake is in the braking position. This means that due to the first spring force F _{BF of} the at least one brake spring _BF presses the movable brake unit 3 with the brake pad 2 against the brake disc 1. On the opposite side of the brake unit 3 presses a further brake unit 9 with a brake pad 2 against the brake disc 1. The braking force of the first spring force F _{BF of} the at least one brake spring BF corresponds to the counteracting normal force or resultant force F _N and thus the maximum braking force, So F _N = F _BF .

In the braking position of the elevator brake, no lifting or no movement is generated by the lifting unit 5. Thus, neither a movement of the brake unit 3 is generated in the axial direction nor the balancing spring AF is tensioned. The actuator 8 may be in a position A, a starting position in this situation.

FIG. 2 shows the according FIG. 1 described elevator brake in a controlled braking position. For this purpose, the actuator 8 is brought into a position B, which leads to a generation of a stroke H ₁ or a movement by the lifting unit 5, which stroke H _{1 has} a tension of the compensating spring AF result. In this example, the stroke H _{1 of} the lifting unit 5 is generated by a Kugelkalotteneinheit. The greater the generated stroke H _{1 of} the lifting unit 5, the greater is the second spring force F _{AF of} the tensioned compensating spring AF. Position B is not a discrete position. Rather, this means that in position B, although there is a reduced but still existing braking effect of the elevator brake.

Due to the generation of the stroke H _{1 of} the lifting unit 5, the first spring force F _{BF of} the at least one brake spring BF or the amount of the first spring force F _{BF is} reduced by the second spring force F _{AF of} the compensating spring AF or by the amount of the second spring force F _AF , The resulting force F _N or the remaining braking effect can thus be described by the formula F _N = F _BF -F _AF .

FIG. 3 shows the according to the FIGS. 1 and 2 described elevator brake in a starting position. In this starting position there is no braking effect, ie the elevator brake is opened or released. This can be achieved by bringing the actuator 8 into a position C so that the second spring force F _{AF of} the compensation spring is equal to or greater than the first spring force F _{BF of} the at least one brake spring BF. The resulting force F _N is F _N = 0. By shifting or turning the actuator 8 in the position C, the lifting unit 5 generates such a large stroke H ₂ or movement, so that the brake unit 3 with the brake pad 2, which is moved in the axial direction, no longer has contact with the brake disc 1 and the second spring force F _{AF of} the compensating spring AF of the amount equal to or greater than the amount of the first spring force F _{BF of} the at least one brake spring BF. Also, the brake unit 9 with the brake pad 2 no longer presses against the brake disc 1, so that there is no braking effect of the elevator brake.

FIG. 4a shows a plan view of an exemplary Kugelkalotteneinheit with three Huberzeugungseinheiten 5.1 and Kalotten K1, K2 and K3, as it can be used for example as a lifting unit 5 according to the invention. The Kugelkalotteneinheit has, for example, a circular shape in plan view. In this example, a plan view is intended to mean a section through the surface (yz-plane) which is defined by the y-axis and the z-axis of a Cartesian coordinate system. A Kugelkalotteneinheit is basically, as in the Figures 4b and 4c represented, from at least one first dome-equipped unit 16 and ideally a second unit 17, which is used as a deck unit for the first unit 16 and balls or rollers, which are embedded in mostly identical calotte K1, K2, K3 and thus between the first 16 and the second unit 17 are arranged. In the Figures 4b and 4c is a so-called Doppelkalotteneinheit shown. Such a Doppelkalotteneinheit consists of two superimposed simple Kalotteneinheiten. On the one hand, a double-dome unit has the advantage that a larger stroke can be generated and, on the other hand, only the second unit 17 must be moved or rotated against the first units 16, and the first units 16 can be designed to be rotationally fixed. In this embodiment, the angle between a dome K1, K2, K3 is 120 degrees. This is to be understood that the calottes K1, K2, K3 are arranged symmetrically on the circular surface of the first unit 16. Of course, the number and the angle between the calotte K1, K2, K3 are arbitrary. In the calotte K1, K2, K3 each a ball of steel, plastic, ceramic etc. is embedded.

If the second unit 17 is rotated about the x-axis against the first units 16 of the spherical cap unit, the balls or rollers in the elevator units 5.1 or calottes K1, K2, K3 are moved from a first position P1 to a second position P2 and This results in a stroke H in the x-axis at the dome unit or lifting unit 5, which for the method according to the FIGS. 1 to 3 is used.

Figures 4b and 4c show a cross section of the dome unit according to FIG. 4a along the straight line AA through the calotte K2 or Huberzeugungseinheit 5.1. The calotte K2 has a pitch α. A ball 7 is located with its geometric center at a position P1 or in its initial position in the calotte K2. In the starting position, the stroke H of the cap unit is equal to zero (H = 0). Will, as in FIG. 4a described, the second 17 is rotated against the first units 16, the ball 7 moves from the position P1 or from its initial position to a position P2, as in Figure 4c is shown. This results in a stroke H = H ₁ or H ₂ , which is in principle a maximum in a simple Kalotteneinheit as large as the diameter of the ball 7 and in the Doppelkalotteneinheit correspondingly larger.

FIG. 5 shows a brake diagram of the inventive elevator train brake. One according to the Figures 1 to 4b Hub H generated by the lifting unit 5 is applied against a force F. This results in a curve F _N (H) of the normal force or resultant force and a curve F _AF (H) of the (second) spring force of the compensating spring AF.

If the spring force F _{AF increases} due to the generation of the stroke H, H ₁ , H _{2 of} the lifting unit 5, the braking effect of the elevator brake is reduced further, as can be seen from the area RBM. From a point DB there is no more braking effect. The theoretical curve of the spring force F _{AF is shown} in dashed line in the diagram. The resultant force F _N from the second spring force F _AF plus the first spring force F _BF is less than the theoretical spring force from the second spring force F _AF .

FIG. 6 shows a further schematic example of an embodiment of an elevator brake according to the invention, as shown in the FIGS. 1 to 3 is described. For clarity, no housing is shown in this embodiment. The elevator brake has a brake unit 3 with a brake pad 2, which presses against a brake disk 1 and thus achieves a braking effect, for example, of an elevator car. In an inactive position, ie the brake unit 3 with the brake pad 2 does not press against the brake disc 1, the brake unit 3 is held by at least one electromagnetic coil 10 in the starting position. Instead of the at least one electromagnetic coil 10, of course, a mechanical holding device for the brake unit 3 could be used.

The brake unit 3 is designed by means of a first spring force of at least one brake spring BF, in this example, the brake spring BF designed as a plate spring, pressed against the brake disc 1.

For regulating or controlling the elevator brake, a lifting unit 5 is used. This lifting unit has a first unit 11, which is connected via a pull unit 6, in this example, the at least one rope, wire rope, plastic rope, etc., with a second unit 12. The first 11 and the second unit 12 may be made of metal, plastic, ceramic, etc. The first unit 11 is connected to the brake unit 3, so that the tractor unit 6 is in operative connection with the brake unit 3. The shape of the first 11 and the second unit 12 depends on the construction of the elevator brake and / or the type of lifting unit 5. The second unit 12 also has an actuator 8, in this example this is a manually operated lever on. Of course, an actuator 8 can be used, as in the FIGS. 1 to 3 is described. Also could be used as a traction unit 6 instead of at least one rope, wire rope, etc., a spindle unit, a screw unit, a hydraulic cylinder, etc. Between the first 11 and the second unit 12 is a balance spring AF, in this example, this is a plate spring.

Due to a movement of the lifting unit 5, ie a rotation of the second unit 12 against the first unit 11, with the actuator 8, the brake unit 3 is moved via the tractor unit 6 in the axial direction and the balancing spring AF is tensioned. The rotation or rotation of the second unit 12 against the first unit 11 takes place in this example about the x-axis. The FIG. 6a shows a section through the xy plane of a Cartesian coordinate system.

FIG. 6b shows a section through the zy plane of the Cartesian coordinate system. The first unit 11 rotates during rotation either not or against the direction of rotation of the second unit 12. Thus, the first spring force of the brake spring BF is reduced by a second spring force of the balance spring AF, so that the resultant force, as already in the FIGS. 1 to 5 is calculated from the formula F _N = F _BF - F _AF .

The reduction of the first spring force F _{BF of} the brake spring BF can be done in addition to the use of the second spring force F _{AF of} the compensating spring AF, that in addition an electromagnetic force F _M of at least one electromagnetic coil 10 is used. This possibility for additional reduction of the first spring force F _{BF of} the brake spring BF can also in the embodiment according to the FIGS. 1 to 3 be used. The at least one electromagnetic coil 10 could also be used so that the elevator brake is fully vented, ie the magnetic force F _M is either greater than the first spring force F _BF with or without the second spring force F _AF , the at least one brake spring BF and the the resulting force is F _N = 0. Thus, the first spring force F _{BF is} canceled either with or without the second spring force F _AF by the magnetic force F _M. A venting of the elevator brake means that the brake unit 3 does not cause any braking action and, for example, with the brake pad 2 no longer has any contact with the brake disk 1. For this purpose, the elevator brake according to the FIGS. 1 to 3 at least one electromagnetic coil 10, which may be arranged for example in the housing 4.

The electromagnetic force F _M can by means of a control unit, as in the FIGS. 1 to 3 and 7 is described, be regulated. Of course, the control unit could control or regulate both the electromagnetic force F _{M of} the at least one electromagnetic coil 10 and also the actuator 8 or the lifting unit 5. From the use of the electromagnetic coil 10 and the compensating spring AF for the control or regulation of the elevator brake is obtained as a formula for the resultant force F _N = F _BF - F _AF - F _M.

FIG. 7 shows a control system for a controlled elevator brake according to the FIGS. 1 to 6 , As in the FIGS. 1 to 6 is described, is generated by the actuator 8 in the lifting unit 5, a stroke H, H ₁ , H ₂ and thus regulated the elevator brake. The control or regulation of the actuator 8 is performed by a control unit 14, which may be, for example, the elevator control or a separate control unit. For controlling or controlling the elevator brake, the control unit 14 receives data or parameters from at least one sensor unit 15. These data or parameters can be, for example, position, speed, acceleration data or parameters, etc. As the sensor unit 15, any sensor unit which can provide the required data can be used. For example, an acceleration sensor, a position sensor, an incremental motor, a speed sensor, etc. could be used. be used. As a function of a comparison, an analysis, an evaluation of data or parameters received from the sensor unit 15, the control unit 14 controls the actuator 8 and thus the lifting unit 5. Thus, the braking effect or the deceleration of the elevator brake is regulated. Of course, it is conceivable that the control unit 14, the lifting unit 5 and / or the at least one electromagnetic coil FIG. 6 controls or regulates. In the lifting unit 5, the actuator 8 may be integrated.

Claims (10)

1. Method of controlling a lift brake comprising a housing (4) and a brake unit (3), which is movable in axial direction on a path between a braking position and a starting position and is disposed in operative connection with at least one pull unit (6) and which is moved at least by means of a first spring force (F_BF) of at least one brake spring (BF), wherein a movement in axial direction against the spring force (F_AF) of the at least one brake spring (BF) is generated by means of a stroke unit (5), which generates a stroke (H, H₁, H₂), at the pull unit (6) of the brake unit (3), characterised in that the first spring force (F_BF) of the at least one brake spring (BF) is reduced by means of a second spring force (F_AF) of a compensating spring (AF) stressed by the stroke (H, H₁, H₂) of the stroke unit (5).
2. Method according to claim 1, characterised in that the compensating spring (AF) is arranged in or near the stroke unit (5).
3. Method according to claim 2, characterised in that at least one ball cap unit, a non-self-locking thread, a spindle unit or a plate spring unit is used as stroke unit (5).
4. Method according to claim 1, characterised in that the pull unit (6) of the brake unit (3) is so arranged that it projects through the housing (4).
5. Method according to any one of the preceding claims, characterised in that the movement in axial direction is executed by the brake unit (5) by means of at least one actuator (8) connected with the stroke unit (5).
6. Method according to claim 5, characterised in that a manually operable lever, a motor-spindle unit, a stroke magnet, a motor or a hydraulic unit is used as at least one actuator (8).
7. Method according to claim 6, characterised in that the at least one actuator (8) is controlled by a control unit (14) connected with the at least one actuator (8).
8. Method according to claim 1, characterised in that the stroke unit (5) is controlled by the control unit (14).
9. Method according to claim 1, characterised in that the first spring force (F_BF) of the at least one brake spring (BF) is either reduced or cancelled by means of the second spring force (F_AF) of the compensating spring (AF) and an electromagnetic force (F_M) of at least one electromagnetic coil (10).
10. Device for controlling a lift brake comprising a housing (4) and a brake unit (3) movable in axial direction on a path between a braking position and a starting position, wherein the brake unit (3) is operatively connected with at least one pull unit (6), wherein the brake unit (3) moves due to a first spring force (F_BF) of at least one brake spring (BF), and wherein a stroke unit (5), which generates a stroke (H, H₁, H₂), at the pull unit (6) of the brake unit (3), generates a movement in axial direction against the first spring force (F_BF) of the at least one brake spring (BF), characterised in that a second spring force (F_AF) of a compensating spring (AF), which is stressed by the stroke (H, H₁, H₂) of the stroke unit (5), reduces the first spring force (F_BF) of the at least one brake spring (BF).

Images