EP2463223A1 - Method and device for monitoring the stopping position of a lift cabin - Google Patents

Abstract

The device has a monitoring device (29) for monitoring whether an elevator car (8) is found within the predetermined tolerance level during its stopping. An actuator is provided for releasing a braking device for the elevator car, if the elevator car is not found within the predetermined tolerance level. An independent claim is also included for a device for controlling stopping position of an elevator car within a predetermined height tolerance relative to a floor level.

Description

The present invention relates to an apparatus and a method for controlling the stopping position of an elevator car within a predetermined height tolerance with respect to a floor level according to the preamble of patent claims 1 and 17.

A technical problem of conventional passenger or goods lifts is that the elevator car in unfavorable traction of the support means or improper use, in particular overload, makes an uncontrolled movement of the floor with an open door. This circumstance may additionally be adversely affected, e.g. due to excessive humidity, unintentional contact of the suspension elements with operating fluids (for example oil, grease), the operating temperature or longer downtimes of the elevator.

Such uncontrolled movements of the floor with an open door are not only a hindrance when entering or loading the elevator car, but also pose a significant risk potential for the passengers. This danger potential can occur in all elevators, which have a support means.

Not least for this reason, the European standard for lifts EN 81-1: 1998 and EN 81-2: 1998 has been extended by Annex A3: 2009, which came into force on 1 July 2010. By this Annex A3: 2009 is in particular a height tolerance to be maintained stop position of the elevator car with respect to the floor level specified. Accordingly, after an uncontrolled movement with an open door, the elevator car must come to a standstill at the latest after 1200 mm distance from the floor level. The upper access edge to the elevator car must be spaced from the floor level by at least 1000 mm if the elevator car is too low or the cabin floor is too high if the elevator car is too high. In addition, there may be at most a clearance of 200 mm in the lower area of the cabin access.

The recently adopted Annex A3: 2009 therefore requires a recertification of certain safety components and, if necessary, a rebuilding of the existing elevators, which may require substantial new investments.

On this basis, the invention has for its object to provide a device and a method of the type mentioned, by which the most secure possible compliance with the specified height tolerance is guaranteed. A further object of the invention is to make the requirements of the European standard EN 81-1 + A3: 2009 and EN 81-2 + A3: 2009 achievable for elevator systems by means of a device mentioned at the outset and such a method. Yet another object of the invention is to allow as simple as possible and cost-effective retrofitting of elevators already in operation in view of EN 81-1 + A3: 2009 and EN 81-2 + A3: 2009.

At least one of these objects is achieved by the device according to claim 1 and the method according to claim 17. The further claims indicate preferred embodiments.

According to the invention, therefore, it is proposed that the device comprises the following components: a monitoring device for monitoring whether the elevator car is within the predetermined height tolerance during its stopping, and an actuator for triggering a braking device for the elevator car, if the elevator car is not within its stopping position the specified height tolerance is.

By such Absinkschutzvorrichtung compliance with the specified height tolerance of the elevator car can be ensured during their stopping time with a high level of security. An uncontrolled up and / or down movement of the elevator car outside the specified height tolerance can be effectively avoided. By Absinkschutzvorrichtung preferably both a lower and a higher-lying stop position of the elevator car is prevented in relation to the height tolerance to the floor level. Preferably, the given height tolerance is selected such that it complies with Annex A3: 2009 of the European standard for lifts, in particular with the European Standard

EN 81-1 + A3: 2009 and EN 81-2 + A3: 2009 and their implementation in country-specific national standards.

For a simple implementation of such a monitoring device, it is proposed that the monitoring device preferably has a marking device with at least one detectable tolerance marking for the predetermined height tolerance and a detection device for determining a relative position of the elevator cage with respect to the Includes tolerance marking, wherein the actuator is designed to trigger the braking device, if the relative position is not detected within the tolerance marking.

Preferably, the Absinkschutzvorrichtung has a static component, which is stationary locatable in the elevator shaft, and a moving component, the nachortbar the travel movement of the elevator car, wherein the marking device and the detection device are formed by these components. This allows a simple and accurate determination of the relative position of the elevator car.

Preferably, one of these components has the marking device and the other component comprises the detection device. This allows easy installation in already in operation located elevators. For example, the marking device can be arranged stationarily in the elevator shaft and the detection device follows the travel movement of the elevator car, which allows a particularly simple installation. For this purpose, the detection device can for example be mounted directly on the elevator car. Alternatively, the marking device of the driving movement of the elevator car can be arranged subsequently and at least one detection device in the elevator shaft.

According to another preferred embodiment, both the marking device and the detection device are formed by only one of the components, that is to say either by the static or the moving component. For example, the Detect detectable tolerance marking the height of a detection surface of a receiver, which is arranged either static in the elevator shaft or the driving movement of the elevator car with nachfol. In this case, the other component supplies, for example, a transmission signal to be detected by this detection surface in order to be able to determine the relative position of the elevator car. It may be, for example, a light emitter, which is arranged either statically in the elevator shaft or with the elevator car.

According to a further embodiment, the monitoring device can only consist of a static component. For example, the tolerance marking can be formed by at least one transmitter / receiver unit, which is arranged statically in the elevator shaft at a suitable marking position of the tolerance height. In this case, the detection device of this transmitter / receiver unit, by which the relative position of the elevator car is detected. For example, for this purpose, an optical or acoustic distance measuring device for detecting the elevator car can be arranged in the elevator shaft. The inventive device can be realized only by such a static component, which is arranged stationarily in the elevator shaft, ie in particular without a moving component.

In the same way, the tolerance marking can be formed by an inductive or capacitive proximity switch or a magnetic switch or a mechanical switch, in particular a roller switch. In this case, the monitoring device preferably includes both a static and a traveling component.

To ensure increased reliability, it is proposed that the Absinkschutzvorrichtung is preferably coupled to the opening mechanism of the elevator door, so that the actuator only during a predetermined period of time before and / or after the opening of the elevator door and / or when the elevator door to trigger the Braking device is formed, most preferably only when the elevator door is open. As a result, an uncontrolled movement of the elevator car from the floor with an open door can be effectively avoided. In addition, in this way a simple means for determining a stopping time of the elevator car is provided.

Preferably, the actuator comprises at least two mutually coupled logical switching means, in particular relays and / or transistors. In this way, a cost-effective, yet safe Absinkschutzvorrichtung can be realized. Most preferably, a switch for coupling to the opening mechanism of the elevator door is integrated into the actuator in order to avoid false triggering of the braking device in the manner described above.

Increased operational safety is preferably also achieved by one or more alternative energy source (s) through which the anti-sabotage device can be operated independently of the power supply of the elevator controller. In this way, the Absinkschutzorrichtung can be realized as an autonomously operating system, which is usually mitversorgt by a conventional power supply, in particular the elevator power supply, and if necessary, by the additional Enerqiequelle is supplied. For example, an accumulator which can be charged by the elevator power supply can be used as such an emergency buffer.

Preferably, the reliability is further increased by the fact that in addition to the alternative energy source, a safety circuit is provided, through which the elevator is set in case of failure of the alternative energy source out of service. This can be achieved, for example, by activating by the safety circuit the fire control of the elevator or a device for immobilizing the elevator acting in the same way when the alternative energy source fails or has a low energy level.

In addition, an increased reliability is preferably achieved in that the circuit of the Absinkschutzvorrichtung is disconnected from the elevator control, that operates independently of the state of the elevator control.

Furthermore, a restart circuit is preferably provided to increase the reliability, after the activation of a triggering of the braking device is prevented by the actuator and the elevator car can be moved from a position between two floor levels to an adjacent floor level. For example, it may happen in the course of malfunction that the elevator car with open elevator door next to the actually intended door zone area of the floor level passes. As a result, it can happen that the elevator with people trapped in it comes to a standstill between two storey levels. By the inventive Restart circuit emergency relief of trapped persons can be carried out in particular by instructed personnel.

Preferably, the restart circuit is activated when, after a query relevant safety states by safety switch or safety devices, the elevator car has been released to leave the stop position and / or the elevator car has left its defined by the given height tolerance protection zone in normal driving.

Preferably, such a restart circuit is realized such that after leaving the elevator car of the respective monitoring zone, which is preferably determined by the predetermined height tolerance, the restart circuit is set remanent by one or more signals. The restart circuit is temporarily activated until the elevator car reaches a next monitoring zone.

Preferably, the device also has a manually operable maintenance circuit to prevent false triggering of the braking device, for example, during the performance of maintenance. The maintenance circuit enables a demand-based deactivation of the Absinkschutzvorrichtung, whereby at the same time the fire control or a device acting in the same way to shut down the elevator is activated. This ensures that the elevator can not be accidentally put into operation upon actuation of the maintenance circuit, ie during deactivation of Absinkschutzes.

The above provisions for increasing operational safety can be used in particular to meet the requirements of Annex A3: 2009 of the European standardization for lifts and their corresponding implementation in national national standards. Preferably, these provisions for increasing the reliability together with the circuit for the actuator and the detection device are integrated in a circuit, whereby a compact design and a simple installation of Absinkschutzvorrichtung is enabled.

In addition, a simple installation of Absinkschutzes in elevators already in operation is preferably made possible by a tolerance marking, which is formed by the height diameter of a arranged on the inner wall of the elevator shaft and / or on the outer wall of the elevator car detection surface. For example, one of the inner wall of the elevator shaft substantially perpendicular or obliquely protruding detection surface, in particular a sheet metal or the like, are arranged, the height diameter of which corresponds to the predetermined height tolerance. By means of such a simply attachable detection surface, a permitted stopping area for the elevator car in the respective floor level is preferably completely marked, with both too high and too low a stop position of the elevator car being detectable by the areas located above and below the detection area.

Preferably, the marking device comprises a plurality of spaced-apart tolerance markings, which are each assigned to a floor level, so that the Absinkschutz can be used in the respective floor levels. For example, the tolerance labels can each be formed by a detection surface described above, which are each arranged in the door zone area of a respective floor level. Alternatively, the detection surfaces can also be arranged between the door zone areas of the floor levels, and the tolerance marking can be formed by a spacing area between two such detection areas.

Furthermore, it is conceivable that, for example, a continuous sensor strip is used in the elevator shaft as a monitoring device, by which the instantaneous position of the elevator car can be determined substantially over the entire elevator shaft. In this case, the tolerance marking may be defined by predetermined electronic position data, by which the predetermined height tolerance and / or the relative spacing between the tolerance markings is taken into account. The monitoring device can be designed, for example, to carry out a data comparison between the data of the current position of the elevator car and the data of the tolerance marking in order to determine the relative position of the elevator car in relation to the tolerance marking.

According to an alternative embodiment, it is proposed that the detection device comprises a plurality of spaced-apart detection units, which are each assigned to a floor level. For this purpose, for example, at least one tolerance marking can be arranged on the elevator car. This tolerance marking on the elevator car can be obtained from the respective detection unit be detected in the door zone area of the individual floor level.

For reliable detection of the tolerance marking, it is proposed that the detection device is preferably designed for encompassing the tolerance marking on both sides, in order to be able to determine the relative position of the elevator car. For example, the detection device may be formed on its front side substantially U-shaped. Preferably, a transmitting / receiving unit is provided in the two embracing sides of the detection device, by which it can be determined whether the tolerance marking is positioned between these pages or not, in order to determine the relative position of the elevator car.

With regard to the braking device, which can be triggered by the actuator, a brake system which is as secure as possible is preferably used in order to reliably prevent an uncontrolled movement of the elevator car outside the height tolerance of the floor level. This is preferably a braking device which acts directly on the elevator car and / or on the counterweight and / or on the suspension means of the elevator car. Preferably, an alternative braking device is used to the brake during normal operation of the elevator, which conventionally acts on the drive of the elevator. For example, for this purpose, an existing emergency braking device or a brake system acting similarly can be used.

Preferably, the speed limiter of the elevator is used to activate the braking device, which meets the high safety requirements. moreover The use of the speed limiter allows a simple and cost-effective installation of Absinkschutzes in already in operation located elevators. Preferably, the release of the speed limiter is effected by a magnet. Most preferably, the magnet activates a mechanical device for applying force, in particular a prestressed spring, in order to permanently hold the triggering device in the triggered position. As a result, a permanent use of the magnet can be avoided and energy for operating the magnet can be saved.

The present invention further relates to a device by which a simple and safe provision of a triggered braking device for elevator systems should be made possible. Namely, conventional brake devices have the disadvantage that such a provision is possible only in the immediate vicinity of the braking device. For example, after a release of the braking device by the speed limiter of the elevator, the service technician must go into the elevator shaft to make the elevator operational again, which requires a considerable amount of work and also causes certain accident hazards.

According to the invention, this problem is solved by a device with a remote line, via which the braking device is operatively connected to a manual actuating device, so that a reset of the triggered braking device is made possible by the actuating device. Such a remote reset is preferably operatively connected to the speed limiter of the elevator. The actuator can for example, be attached to the side of an elevator door. Preferably, the transmission line is formed by a cable, in particular a Bowden cable. Alternatively, an electrical line can be used for this purpose.

The inventive remote reset is preferably used in combination with the inventive Absinkschutzvorrichtung. This has the advantage that when the braking device is activated by the actuator of the sinking protection, a simple return of the braking device is made possible. In particular, in older elevator systems, it can often happen that the braking device is activated by the inventive fall protection, in particular for compliance with Annex A3: 2009 of the European standardization for lifts.

However, as will be readily apparent to one skilled in the art, the remote reset of the present invention may be used without the anti-saber device, and thus constitutes an independent invention.

With regard to the method mentioned at the outset, it is proposed according to the invention that the method comprises the steps of monitoring during the stop of the elevator car whether the elevator car is within the specified height tolerance and that a brake device for the elevator car is triggered when the elevator car is not within the specified height tolerance while pausing.

Preferably, for monitoring the elevator car, at least one tolerance marking for the predetermined Height tolerance provided and determines the relative position of the elevator car with respect to the tolerance marking, wherein the brake device for the elevator car is triggered when the relative position is not detected within the tolerance marking.

Preferably, the method according to the invention is carried out only during a predetermined time period before and / or after the opening of the elevator door and / or with the elevator door open, most preferably only when the elevator door is open. For this purpose, it may be provided that a device for carrying out the method is coupled to the opening mechanism of the elevator door, as has already been described above with reference to the inventive anti-jacketing device.

The further method steps according to the invention also follow directly from the sink protection device described above and the subsequent description of preferred embodiments. Preferably, the device according to the invention is used to carry out this method.

Fig. 1:

eine perspektivische Ansicht einer Aufzuganlage mit einer erfindungsgemässen Vorrichtung;

Fig. 2:

eine Detailansicht der in Fig. 1 gezeigten Aufzuganlage;

Fig. 3:

eine schematische Ansicht einer elektrischen Schaltung gemäss einer ersten Ausführungsform der Erfindung;

Fig. 4:

eine schematische Ansicht einer elektrischen Schaltung gemäss einer zweiten Ausführungsform der Erfindung;

Fig. 5:

eine schematische Ansicht einer elektrischen Schaltung gemäss einer dritten Ausführungsform der Erfindung; und

Fig. 6:

eine schematische Ansicht einer erfindungsgemässen Fernrückstellung.

The invention is explained in more detail below with reference to preferred embodiments with reference to the drawings, on the basis of which further properties and advantages of the invention result. The figures, the description and the claims contain numerous features in combination which the skilled person will also consider individually and summarize to meaningful further combinations. Showing:

Fig. 1:

a perspective view of an elevator system with an inventive device;

Fig. 2:

a detailed view of in Fig. 1 shown elevator installation;

3:

a schematic view of an electrical circuit according to a first embodiment of the invention;

4:

a schematic view of an electrical circuit according to a second embodiment of the invention;

Fig. 5:

a schematic view of an electrical circuit according to a third embodiment of the invention; and

Fig. 6:

a schematic view of an inventive remote reset.

An in Fig. 1 shown elevator installation 1 comprises three floor levels 2-4 with a respective elevator door 5-7. On the top floor level 4 is an elevator car 8 in its stop position. By means of the elevator motor 9 or an emergency relief device, the elevator car 8 can be moved between the individual floor levels 2-4.

In addition to the elevator motor 9, a speed limiter 10 is arranged, by means of which a safety brake is activated when the elevator car 8 is too high in acceleration. The speed limiter 10 comprises a rope pulley 11 for a safety rope and a triggering device 12, which can be activated for example via a remote release.

To reset the triggering device 12 from its activated position, a remote reset 13 is provided. The remote reset 13 comprises a cable 14 through which the triggering device 12 is operatively connected to an actuating switch 15 on the side of the uppermost elevator door 7. By pressing or pulling the operating switch 15, the triggering device 12 can thus be returned to its non-activated position.

On the cabin roof 16 of the elevator car 8, a detection device 20 is arranged such that it projects beyond the cabin side wall 17. The protruding part 21 of the detection device 20 has a substantially U-shaped configuration. In the two parallel sides of the protruding part 21, a light emitter and a light receiver is arranged, so that an object located between these sides causes an interruption of the light beam and can be detected in this way.

In the upper door zone area of each floor level 2-4, a detection surface 25-27 is arranged stationarily in the elevator shaft in such a way that the transmitter / receiver unit of the detection device 20 is guided past the detection surfaces 25-27 when the elevator car 8 moves between the floor levels 2-4 whereby the relative position of the elevator car 8 with respect to its current location area is within or outside the area indicated by the detection areas 25-27 can be determined. In this case, the detection surfaces 25-27 are each formed by a metal sheet which is substantially perpendicular to the inner wall of the elevator shaft.

The height of the detection surfaces 25-27 each indicates a predetermined height tolerance, within which the elevator car 8 may be removed from the respective floor level 2-4 according to the Annex A3: 2009 of the European standard for lifts during their stopping. In this way, a tolerance marking 25-27 for the given height tolerance with respect to a respective floor level 2-4 is formed by the detection surfaces in each case.

Due to the relative arrangement of the tolerance markings 25-27 together with the intermediate and upper and lower free spaces, a marking device 28 is thus provided, by means of which detection means 20 a deviation from the predetermined height tolerance during the stopping of the elevator car 8 can be determined. By the interaction of the detection device 20 and the marking device 28 is thus a monitoring device 29 for monitoring whether the elevator car 8 is during its stopping within the predetermined height tolerance, provided.

In the in Fig. 2 In particular, the detection device 20, the upper and middle tolerance marking 27, 26 and the remote reset 13 are again shown in an enlarged form.

Fig. 3 shows an electrical circuit 30 a Absinkschutzvorrichtung according to a first embodiment.

Here are the in Fig. 1 and 2 shown upper floor level 4, the tolerance marking 27, the detection device 20, the speed limiter 10 and the remote reset 13 also shown schematically. The circuit 30 represents a largely autonomously operating system which is decoupled from the actual elevator control.

The circuit 30 of the Absinkschutzvorrichtung has an accumulator 31 for on-demand autonomous power supply, which is charged in normal operation by the power supply of the elevator and ensures trouble-free operation of the Absinkschutzvorrichtung even in case of failure of this external power supply. Should the alternative emergency power-buffered power supply fail, for example, if a too low energy level of the accumulator 31 is detected, the elevator is automatically put out of operation by the fire control. The fire control circuit 39 is also schematically shown in FIG Fig. 1 shown.

The circuit 30 comprises a first relay, hereinafter referred to as door zone relay 32, and its load current side 32L and control current side 32C separately in FIG Fig. 3 are shown. The load current side of the first relay 32L is additionally integrated into the fire-control control circuit 39. The circuit 30 further comprises a second relay, which is referred to below as Absinkschutzrelais 33 and its load current side 33L and control current side 33C also separately in the circuit 30 according to Fig. 3 drawn are. Further, a door contact switch 34 coupled to the opening mechanism of the elevator doors 5-7 is integrated in the circuit 30, and a test switch 35 for checking the operation of the circuit 30.

In addition, in the circuit 30, the remote release 36 of the speed limiter 10 is implemented, by which the emergency brake device 37 can be activated. The remote release 36 includes a magnet with a spring for remotely triggering the emergency brake device 37 via the triggering device 12 of the speed limiter 10. In order to prevent burning of the magnet during long-term operation of the same, in the circuit 30 in addition a magnetic circuit breaker 38 is integrated. After triggering the emergency brake device 37 by the remote release 36 of the magnetic circuit breaker 38 is activated, thereby preventing the flow of current through the magnet, the emergency brake 37 remains activated. By resetting the triggering device 12 for deactivating the emergency brake device 37, for example by the remote reset 13, and the magnetic circuit breaker 38 is returned to its original position.

During normal operation of the elevator 1, the series-connected load current side 32L of the door zone relay 32 and the test switch 35 are in the closed state, so that a current flows through the control current side 33C of the sinking protection relay 33. In this state, the load current side 33L of the sinking protection relay 33 is opened, so that no current for activating the remote release 36 can flow.

The position of the door contact switch 34 connected in parallel to the load current side 32L of the door zone relay 32 is coupled to the opening mechanism of the respective elevator door 5-7. While the elevator door 7 is closed, the door contact switch 34 is also closed, so that the control current side 33C of the sinking protection relay 33 is also energized by the door contact switch 34 and the load current side 33L of the sinking protection relay 33 remains open regardless of the switching state of the load current side 32L of the door zone relay 32. As a result, no activation of the remote release 36 can take place even when the elevator door 7 is closed.

Through the door contact switch 34, the circuit 30 is coupled to the opening mechanism of the elevator door 7. When the elevator door 7 is opened, the door contact switch 34 also opens, so that the current flow through the load current side 33L of the sinking protection relay 33 depends only on the switching state of the load current side 32L of the door zone relay 32. If a deviation of the stop position of the elevator car 8 from the tolerance designation 27 of the floor level 4 is detected by the detection device 20, the control current side 32C of the door zone relay 32 is supplied with current. As a result, the load current side 32L of the door zone relay 32 is set in the open state and generates a voltage drop on the control current side 33C of the sinking protection relay 33.

The voltage drop on the control current side 33C causes the load current side 33L of the fall protection relay 33 to close, so that the remote release 36 is activated and thereby the triggering device 12 of the speed limiter 10 is activated. The emergency brake device 37 causes the elevator car 8 to stop within the specified height tolerance. Now the opens Magnetic switch 38, to prevent overheating of the magnet of the remote release 36 by a permanent response of the remote release 36. In addition, the fire alarm control 39 is activated via the load current side 32L of the door zone relay 32.

In this way, a cost-effective yet safe-acting circuit 30 is realized for the Absinkschutzvorrichtung, which can be integrated to save space in the detection device 20 as a single fitting for lifts. By means of such a built-in component 20 and the associated detection device 20, elevators already in operation, in particular, can easily be retrofitted in order to meet the requirements of Annex A3: 2009 of the European standardization for lifts.

Fig. 4 shows an electrical circuit 40 a Absinkschutzvorrichtung according to a second embodiment. The circuit essentially corresponds to the circuit 30 described above Fig. 3 with the difference that a maintenance switch 41 is additionally arranged, which is additionally implemented in the fire control circuit 42.

The maintenance switch 41 is connected in parallel with the load current side 32L of the door zone relay 32 and the door contact switch 34, and is in the open state during normal operation of the elevator 1. For example, during a technical inspection of the elevator installation 1 by technically instructed personnel, the maintenance switch 41 can be closed manually. As a result, on the one hand, the control current side 33C of the sinking protection relay 33 is independent of the position of the load current side 32L of the door zone relay Power supplied to 32 and the door contact switch 34 and to prevent unwanted tripping the Absinkschutzvorrichtung during maintenance.

On the other hand, by closing the maintenance switch 41, the fire control 42 of the elevator installation 1 is activated in order to prevent the elevator 1 from being inadvertently put into operation when the fire protection is switched off. In this way, the operational safety of the elevator installation is additionally increased, in particular with regard to Annex A3: 2009 of the European standardization for lifts.

Fig. 5 shows an electrical circuit 45 a Absinkschutzvorrichtung according to a third embodiment. The circuit essentially corresponds to the circuit 40 described above Fig. 4 with the difference that a self hold circuit 46 is integrated in the circuit.

The self hold circuit 46 includes a third relay, hereinafter referred to as self-holding relay 47, and its two load current sides 47L1, 47L2 and control current side 47C separately in FIG Fig. 5 and a signal switch 48 coupled to the elevator controller. The first load current side 47L1 of the self-holding relay 47 is connected in parallel to the first load current side 32L of the door zone relay 32 and the door contact switch 34, and is in the open state during normal operation of the elevator 1.

The second load current side 47L2 of the self-holding relay 47 and the signal switch 48 are parallel to each other and in series in front of a second load current side 32L2 of Door zone relay 32 and the control current side 47C of the self-holding relay 47 connected. These

Circuit components 32L2, 47L2 and 48 are also in the open state during normal operation of the elevator 1.

By this self-holding circuit according to the invention a restart circuit 46 is realized, which can be used in particular for emergency rescue of persons who were trapped between two adjacent floor levels 2-4 in the elevator car 8. For example, it could happen in case of malfunction of the elevator system 1, that the elevator door 5-7 between two floor levels 2-4 is opened. As a result, the above-described anti-sinking device would be activated and thus the braking device 37 would be used, whereby the elevator car 8 would be blocked in a position of residence between two level levels 2-4. Activation of the restart circuit 46 prevents triggering of the brake device 37 between the stop positions of the floor levels 2-4 and allows the elevator car 8 to be moved by instructed persons to the next door area 5-7 for emergency release of the trapped persons.

For this purpose, after a query of the relevant safety conditions before the departure of the elevator car 8 a short-lasting signal provided by the elevator control, by which the signal switch 48 is briefly moved to the closed position. When the control current side 32C of the door zone relay 32 has previously received a current pulse, ie, after the sinking protection device has been activated, it is to this Time also closed the second load current side 32L2 of the door zone relay 32. It is thus achieved that a brief current flows through the control current side 47C of the self-holding relay 47 due to the short-lasting signal from the elevator control, which leads to a closure of the first and second load current sides 47L1, 47L2 of the self-holding relay 47.

By closing the first load current side 47L1 of the self-holding relay 47, the control current side 33C of the sinking protection relay 33 is energized, so that the load current side 33L of the sinking protection relay 33 is guided from the closed to the opened state.

By closing the second load current side 47L1 of the self-holding relay 47 it is achieved that the control current side 32C of the door zone relay 32 is supplied with constant current until the detection device 20 detects a further deviation of the elevator cage 8 from the tolerance marking 27 of the floor level 4. As a result, the control current side 32C of the door zone relay 32 is again supplied with power and the second load current side 32L of the door zone relay 32 is set in the open state. Due to the resulting voltage drop on the control current side 47C of the self-holding relay 47, the first and second load current side 47L1 of the self-holding relay 47 are returned to the open state.

Due to the resulting voltage drop on the control current side 33C of the sinking protection relay 33, its load current side 33L is closed again and the remote release 36 is addressed. As a result, the triggering device 12 of the Speed limiter 10 is activated and caused by the emergency brake 37 an immediate stop the elevator car 8. In the meantime, the elevator car 8 has been moved by the elevator control to the next door zone area 5-7 of an adjacent floor level 2-4, so that the trapped persons can be released from the elevator car.

Fig. 4 shows the schematic view of the remote reset 13 again in an enlarged view. The remote reset 13 comprises a cable 14 through which the triggering device 12 is operatively connected to an actuating switch 15 on the side of the uppermost elevator door 7. By pressing or pulling the operating switch 15, the triggering device 12 can thus be returned to its non-activated position. According to the invention, a simple possibility is thus provided by the cable realized by the cable 14 to deactivate the triggering device 12. As a result, a renewed transfer of the elevator installation 1 into normal operation without more costly repair measures can be carried out directly on site of the triggering device 12.

Of course, the in Fig. 4 shown remote reset 13 are also used advantageously in elevator systems regardless of the previously described Absinkschutzvorrichtung.

From the foregoing description, the skilled person numerous modifications of the inventive device and the method for controlling the stopping position of an elevator car accessible without the scope of the To leave the invention, which is defined solely by the claims.

Claims (17)

Device for controlling the stopping position of an elevator car (8) within a predetermined height tolerance with respect to a floor level (2, 3, 4), characterized by a monitoring device (29) for monitoring whether the elevator car (8) is within the predetermined height tolerance during its stopping and an actuator (30, 40, 45) for triggering a brake device (37) for the elevator car (8) when the elevator car (8) is not within the predetermined height tolerance. Apparatus according to claim 1, characterized in that the monitoring device (29) has a marking device (28) with at least one detectable tolerance marking (25, 26, 27) for the predetermined height tolerance and a detection device (20) for determining a relative position of the elevator car (8). with respect to the tolerance marking (25, 26, 27), wherein the actuator (30, 40, 45) is designed to trigger the braking device (37) if the relative position is not detected within the tolerance marking (25, 26, 27) , Apparatus according to claim 1 or 2, characterized by a static component, which is stationary locatable in the elevator shaft, and a moving component, the nachortbar the travel movement of the elevator car (8), wherein the monitoring device (29) is formed by these components. Device according to one of claims 1 to 3, characterized in that the monitoring device (29) and / or the actuator (30, 40, 45) is coupled to the opening mechanism of the elevator door (5, 6, 7). Device according to one of claims 1 to 4, characterized by an alternative energy source (31) through which the monitoring device (29) and / or the actuator (30, 40, 45) can be operated independently of the power supply of the elevator control. Device according to Claim 5, characterized by a safety circuit by means of which the elevator is put out of operation in the event of a failure of the alternative energy source (31). Device according to one of claims 2 to 6, characterized in that the tolerance marking (25, 26, 27) is selected such that the thereby specified height tolerance is compliant with the Annex A3: 2009 of the European standardization for lifts, in particular with the European Standard EN 81-1 + A3: 2009 and EN 81-2 + A3: 2009 and their implementation in country-specific national standards. Device according to one of claims 1 to 7, characterized by a manually operable maintenance circuit (41) for on-demand deactivation of the monitoring device (29) and / or the actuator (30, 40, 45), whereby simultaneously the fire control (39, 42) of the elevator or a device acting in the same way to shut down the elevator is activated. Device according to one of claims 1 to 8, characterized by a restart circuit (46), by the activation of which causes the brake device (37) to be triggered by the actuator (30, 40, 45), so that the elevator car (8) moves from a position between two floor levels (2, 3, 4) to an adjacent floor level (2, 3 , 4) can be moved. Device according to one of claims 2 to 9, characterized in that the tolerance marking (25, 26, 27) by the height diameter of at least one in the elevator shaft and / or on the elevator car (8) locatable detection surface is formed. Device according to one of claims 2 to 10, characterized in that the detection device (20) is designed for embracing the tolerance marking (25, 26, 27) on both sides so as to be able to determine the relative position of the elevator car (8). Device according to one of claims 1 to 11, characterized by a remote reset (13) with a remote line (14) via which the braking device (37) with a manual actuator (15) is operatively connected, so that by the actuating device (15) a provision the triggered braking device (37) is enabled. Apparatus according to claim 12, characterized in that the transmission line (14) is formed by a cable and / or by an electrical line. Device according to one of claims 1 to 13, characterized in that the by the actuator (30, 40, 45) releasable braking device (37) directly to the elevator car (8) and / or on a counterweight (8) and / or on a suspension means of the elevator car (8) acts. Device according to one of claims 1 to 14, characterized in that the braking device (37) via the speed limiter (10) of the elevator (1) is triggered. Device according to one of claims 1 to 15, characterized in that the marking device (28) comprises a plurality of spaced-apart tolerance markings (25, 26, 27) which are each associated with a floor level (2, 3, 4). A method for controlling the stopping position of an elevator car (8) within a predetermined height tolerance with respect to a floor level (2, 3, 4), characterized in that is monitored during the stop of the elevator car, whether the elevator car (8) is within the predetermined height tolerance and in that a braking device (37) for the elevator car (8) is triggered when the elevator car (8) is not within the specified height tolerance.

Images