This application claims priority to European Patent Application No. 18208158.8, filed Nov. 23, 2018, and all the benefits accruing therefrom under 35 U.S.C. § 119, the contents of which in its entirety are herein incorporated by reference.
The invention relates to an elevator safety system, in particular to an elevator safety system comprising self-diagnostics functionality. The invention further relates to an elevator system comprising such an elevator safety system, and to a method of operating such an elevator system.
An elevator system typically comprises at least one elevator car moving along a hoistway between a plurality of landings, and an elevator drive, which is configured for driving the elevator car. For securing safe operation, the elevator system may comprise an elevator safety system configured for monitoring the operation of the elevator system and for stopping any further movement of the elevator car in case a safety related issue is detected. The elevator safety system may comprise a self-diagnostic functionality in order to ensure that the elevator safety system operates correctly.
It is desirable to reduce the risk of false alarms triggered by the elevator safety system, in particular triggered by the self-diagnostic functionality of the elevator safety system, in order to prevent unnecessary shutdowns of the elevator system.
According to an exemplary embodiment of the invention, an elevator safety system for an elevator system comprises a self-diagnostics functionality including at least two safety channels. Each safety channel is configured for supplying a safety signal in case a safety issue has been detected. The elevator safety system further comprises a self-diagnostic evaluator, which is configured for receiving any safety signals supplied via the safety channels; starting a timer for measuring a predetermined period of time in case a safety signal has been supplied on one of the safety channels; and stopping any further operation of the elevator system in case the safety signal is still supplied after the predetermined period of time has expired.
Exemplary embodiments of the invention further include an elevator system comprising an elevator safety system according to an exemplary embodiment of the invention.
Exemplary embodiments of the invention also include a method of operating an elevator safety system with a self-diagnostics functionality including at least two safety channels, wherein each safety channel is configured for supplying a safety signal in case a safety issue has been detected. The method comprises starting a timer for measuring a predetermined period of time in case a safety signal has been supplied on only one of the safety channels, and stopping any further operation of the elevator system in case the supplied safety signal is still supplied after the predetermined period of time has expired.
Failures of the self-diagnostic functionality may cause temporary safety signals supplied via one of the safety channels of the elevator safety system, which disappear on their own, i.e. without any external measures to be taken. Such temporary safety signals are related to so called “soft errors”. Failures of the self-diagnostic functionality may also cause permanent safety signals related to so called “hard errors”. “Hard errors”, for example, may result from a physical defect of a component of the elevator system.
An elevator safety system and a method of operation an elevator safety system according to exemplary embodiments of the invention allow reducing the risk of unnecessary shutdowns of an elevator system monitored by the elevator safety system due to “soft errors”.
As a result, an elevator safety system and a method of operation an elevator safety system according to exemplary embodiments of the invention enhance the operating time of an elevator system without compromising its safety.
A number of optional features are set out in the following. These features may be realized in particular embodiments, alone or in combination with any of the other features.
Any operation of the elevator system may be stopped in case safety signals are simultaneously supplied on at least two safety channels and/or in case a further safety signal is supplied on another safety channel before the predetermined period of time has expired. In order to maintain the safety of the elevator system, the occurrence of at least two safety signals within the predetermined period of time is interpreted as a severe safety issue resulting in a shutdown of the elevator system.
In order to avoid an unnecessary shutdown of the elevator system in case of “soft errors”, the timer may be reset in case the previously supplied safety signal is not present anymore after the predetermined period of time has expired and no further safety signal has been supplied on another safety channel before the predetermined period of time has expired.
The predetermined period of time may be in the range of 1 second to 15 second. The predetermined period of time in particular may be one of 1 second, 5 seconds, 10 seconds, or 15 seconds, respectively. The inventors have found that a predetermined period of time in the range of 1 second to 15 seconds is well suited for distinguishing between “soft errors” which allow continuing the operation of the elevator system, and “hard errors” which require the elevator system to be shut down in order to avoid an unsafe condition of the elevator system.
The self-diagnostic evaluator may be implemented as a cheap and reliable hardware circuit. Additionally or alternatively, the self-diagnostic evaluator may comprise a microprocessor running an appropriate software program. A microprocessor running an appropriate software program allows providing a flexible self-diagnostic evaluator which may be adjusted easily to different elevator systems by amending the software program.
The elevator safety system may comprise a safety chain, in particular an electronic safety chain including electronic safety nodes. The electronic safety nodes may be connected via a field bus system, e.g. a CAN bus, and the electronic safety nodes may communicate using a serial field bus protocol. The elevator safety system provides self-diagnostic functionality, i.e. the safety condition of the individual safety nodes, and of other safety relevant components of the safety system, may be monitored by particularly programmed self-diagnostic safety routines.
Stopping any further operation of the elevator system may include switching off a motor configured for driving the elevator car. Switching off a motor configured for driving the elevator car is the easiest means for bringing an elevator system into a safe state by stopping any further movement of the elevator car.
Stopping any further operation of the elevator system further may include activating a brake and/or a safety device of the elevator system. This enhances the safety of the elevator system by reliably stopping any further movement of the elevator car independently of a motor, if necessary without delay.
In the following, exemplary embodiments of the invention are described in more detail with respect to the enclosed figures:
The elevator system 2 includes an elevator car 6 movably arranged within a hoistway 4 extending between a plurality of landings 8. The elevator car 6 in particular is movable along a plurality of car guide members 14, such as guide rails, extending along the vertical direction of the hoistway 4. Only one of said car guide members 14 is depicted in
Although only one elevator car 6 is depicted in
The elevator car 6 is movably suspended by means of a tension member 3. The tension member 3, for example a rope or belt, is connected to an elevator drive 5 comprising a motor 18 and configured for driving the tension member 3 in order to move the elevator car 6 along the height of the hoistway 4 between the plurality of landings 8 located on different floors.
The elevator drive 5 further comprises at least one brake 16, which is configured for braking the tension member 3 in order to brake the movement of the elevator car 6.
Each landing 8 is provided with a landing door 11, and the elevator car 6 is provided with a corresponding elevator car door 13 for allowing passengers to transfer between a landing 8 and the interior of the elevator car 6 when the elevator car 6 is positioned at the respective landing 8.
The exemplary embodiment shown in
The elevator system 2 includes further a counterweight 21 attached to the tension member 3 opposite to the elevator car 6 and moving concurrently and in opposite direction with respect to the elevator car 6 along at least one counterweight guide member 15. The skilled person will understand that the invention may be similarly applied to elevator systems 2 which do not comprise a counterweight 21.
The tension member 3 may be a rope, e.g. a steel core, or a belt. The tension member 3 may be uncoated or may have a coating, e.g. in the form of a polymer jacket. In a particular embodiment, the tension member 3 may be a belt comprising a plurality of polymer coated steel cords (not shown). The elevator system 2 may have a traction drive including a traction sheave for driving the tension member 3.
In an alternative configuration, which is not shown in the figures, the elevator system 2 may be an elevator system 2 without a tension member 3, comprising e.g. a hydraulic drive or a linear drive. The elevator system 2 may have a machine room (not shown) or it may be a machine room-less elevator system 2.
The elevator drive 5 is controlled by an elevator control 10 for moving the elevator car 6 along the hoistway 4 between the different landings 8.
Input to the elevator control 10 may be provided via landing control panels 7a, which are provided on each landing 8 close to the landing doors 11, and/or via an elevator car control panel 7b, which is provided inside the elevator car 6.
The landing control panels 7a and the elevator car control panel 7b may be connected to the elevator control 10 by means of electrical wires, which are not depicted in
The elevator car 6 is equipped with at least one elevator safety device 19. The at least one elevator safety device 19 is configured for engaging with the car guide member 14 for braking the elevator car 6 independently of the elevator drive 5, i.e. independently of the motor 18 and the brake 16 of the elevator drive 5.
Alternatively or additionally, an elevator safety device (not shown) may be provided at the counterweight 21.
The elevator control 10 comprises an elevator safety system 20. The elevator safety system 20 is configured for monitoring the operation of the elevator system 2 and for shutting down the elevator system 2 stopping any further movement of the elevator car 6 in case safety issues, such as safety related malfunctions of any components of the elevator system 2, are detected.
The elevator safety system 20 further comprises a self-diagnostic functionality which allows monitoring the operation of the elevator safety system 20 itself and shutting down the elevator system 2 in case a proper and safe operation of the elevator safety system 20 cannot be ensured.
The exemplary embodiment shown in
The safety channels 22a, 22b are configured for controlling safety switches 26a, 26b, which belong to a safety chain (daisy chain) 28 of the elevator system 2. In case a safety signal 23a, 23b is received on at least one of the safety channels 22a, 22b, at least one of the safety switches 26a, 26b is opened due to a corresponding opening signal 29a, 29b supplied from at least one of the safety channels 22a, 22b to the corresponding safety switch 26a, 26b. As a result, the safety chain 28 is interrupted stopping any further movement of the elevator car 6.
The safety chain 28 may be implemented as an electronic safety chain 28 comprising electronic safety nodes 30 connected via a field bus system, e.g. a CAN bus. The electronic safety nodes 30 may communicate using a serial field bus protocol. The elevator safety system 20 provides self-diagnostic functionality, i.e. the safety condition of the individual safety nodes 30, and of other safety relevant components of the safety system 20, may be monitored by particularly programmed self-diagnostic safety routines.
The inventors have found that in a considerable number of cases failures detected by the self-diagnostic functionality and causing a safety signal 23a, 23b to be supplied are only of temporary duration. These cases are called “soft errors”. Only a comparatively smaller number of failures detected by the self-diagnostic functionality are permanent “hard errors”, which for example result from physical defects of components of the elevator system.
In a conventional implementation of a self-diagnostic functionality each detection of an unsafe condition leads to safety signals 23a, 23b supplied on the two parallel safety channels 22a, 22b. Supply of the safety signal on at least one of the safety channels 22a, 22b causes an interruption of the safety chain 28. This results in a relatively large number of shutdowns of the elevator system 2 due to “soft errors” found in the self-diagnosing functionality, which would be unnecessary as the problems causing “soft errors” are only of temporary nature.
An elevator safety system 20 according to an exemplary embodiment of the invention therefore comprises a self-diagnostic evaluator 24 connected to all safety channels 22a, 22b.
In case only one safety signal 23a, 23b is supplied via the safety channels 22a, 22b, the self-diagnostic evaluator 24 is configured for overriding the single opening signal 29a, 29b supplied to one of the safety switches 26a, 26b by supplying an override signal 27a, 27b to the respective safety switch 26a, 26b. The override signal 27a, 27b overrides the opening signal 29a, 29b supplied to the respective safety switch 26a, 26b preventing the safety switch 26a, 26b from opening. In consequence, the safety chain 28 is not interrupted when only a single safety signal 23a, 23b is supplied via one of the safety channels 22a, 22b.
The self-diagnostic evaluator 24 further comprises a timer 25, which is started as soon as a safety signal 23a, 23b is supplied via one of the safety channels 22a, 22b.
The timer 25 expires after a predetermined period of time. In case a safety signal 23a, 23b is still supplied after the timer 25 has expired, the safety signal 23a, 23b is considered as indicating a “hard error”. In consequence, the override signal 27a, 27b is switched off causing the respective safety switch 26a, 26b to open interrupting the safety chain 28 and stopping any further movement of the elevator car 6.
In case, however, no safety signal 23a, 23b is supplied anymore after the timer 25 has expired, the previously supplied safety signal 23a, 23b is considered as indicating a “soft error” which has vanished on its own. Thus, it is not considered necessary to open the safety chain 28 and stop any further movement of the elevator car 6. Instead, the timer 25 is reset, the override signal 27a, 27b is switched off, and normal operation of the elevator system 2 resumes. In such a situation, switching of the override signal 27a, 27b does not cause any of the safety switches 26a, 26b to open, as no safety signal 23a, 23b and in consequence no opening signal 29a, 29b is supplied anymore.
In case, however a second safety signal 23b, 23a is supplied on a second safety channel 23b, 23a before the time 25 has expired indicating that at least two safety relevant issues occurred within the predefined amount of time as defined by the timer 25, the overall safety situation of the elevator system 2 is considered as being critical. In consequence, the override signal 27a, 27b is switched off causing at least one of the safety switches 26a, 26b to open interrupting the safety chain 28 and stopping any further movement of the elevator car 6.
In other words, operation of the elevator system 2 is stopped immediately in case at least two safety signals 23a, 23b are supplied on at least two safety channels 22a, 22b simultaneously or within a predefined period of time.
In case only a single safety signal 23a, 23b is supplied on one of the safety channels 22a, 22b, normal operation of the elevator system 2 is provisionally continued for the predefined period of time. If the detected safety signal 23a, 23b is still supplied after the predefined period of time has expired, operation of the elevator system 2 is stopped.
If the detected safety signal 23a, 23b is not supplied after the predefined period of time has expired, normal operation of the elevator system 2 is continued.
The predefined period of time may be set to a couple of seconds, in particular to 1 to 15 seconds, more particularly 1 second, 5 seconds, 10 seconds, or 15 seconds, depending on the characteristics of the elevator safety system 20 and its self-diagnostic functionality.
The self-diagnostic evaluator 24 and the timer 25 may be implemented as electronic hardware circuits and/or by at least one microprocessor running an appropriate software program.
An elevator safety system 20 and a method of operation an elevator safety system 20 according to exemplary embodiments of the invention allow reducing the risk of unnecessary shutdowns of an elevator system 2 due to “soft errors”, i.e. due to temporary safety signals 23a, 23b supplied on one of the safety channels 22a, 22b of the elevator safety system 20, which disappear on their own, i.e. without any external measures to be taken.
At the same time, an elevator safety system 20 and a method of operation an elevator safety system 20 according to exemplary embodiments of the invention do not deteriorate the safety of the elevator system 2 as the elevator system 2 is shut down in case at least two safety signal are supplied within a predefined period of time and/or a single safety signal 23a, 23b is supplied at least for the predefined amount of time.
Thus, an elevator safety system 20 and a method of operation an elevator safety system 20 according to exemplary embodiments of the invention enhance the operating time of an elevator system 2 without compromising its safety.
While the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adopt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention shall not be limited to the particular embodiment disclosed, but that the invention includes all embodiments falling within the scope of the dependent claims.
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