EP1213248A1 - Safety braking device with braking force adjusted according to the decceleration of the elevator - Google Patents

Abstract

The emergency brake system for an elevator, to stop a dangerous descent of the elevator cage and lock it against the elevator rail (1), has at least one brake wedge (13) to be pressed against the rail by a spring pressure body (14) and apply a braking force. The stroke movement of the brake wedge, during a braking action, is defined by a limit unit (18), to apply a braking force according to the deceleration of the elevator cage. The limit unit is part of a hydraulic system, operated according to the setting of a control valve (21) which reacts to the elevator cage movement sensor (23).

Description

The invention relates to a safety gear with delay-dependent Braking force for a load handling device of an elevator, the at speed of the load handler is triggered by an elevator speed limiter, wherein at least one brake wedge narrows into a Gap between a resiliently supported pressure body Safety gear and a guide rail of the load handler penetrates and thereby generates a braking force, and the magnitude of this braking force from that on the load suspension device occurring delay is dependent.

In conventional safety devices, a safety device base body encompasses the guide web of a guide rail of the load suspension device and contains at least one pressure body which, on the one hand, forms a gap narrowing in the opposite direction to the direction of travel of the load support device and, on the other hand, is movable against a spring element normal to the guide bridge. If the load suspension device is overspeed, a speed limiter mechanism moves a brake wedge into the narrowing gap between the pressure body and the guide web moving relative to this, whereupon the brake wedge is pulled into the narrowing gap by the friction on the guide web up to a stop on the base body and then glides along the guide bar until the load handler stops. The pressure element is displaced against the spring element by the wedge effect. The resulting spring force acts on the brake wedge via the pressure body and determines the normal force occurring between the latter and the guide web and thus the resulting frictional force acting as braking force on the load suspension device.
Such safety devices have the disadvantage that the normal force acting on the brake wedge is always the same, regardless of different payloads in the load suspension device and other influences, such as the condition and contamination of the braking surfaces, the current speed and the ambient temperature. The consequence of this is that, in the event of a fall, there are very different deceleration values on the load handler. As a certain minimum delay must be guaranteed for safety reasons, delay values above the permissible limit often result with a minimal payload.

From DE 3934492 is on the load handling device of an elevator Attached safety device with a pliers not crossing safety arms trained safety gear body known, in which the pliers arms on one side of the pliers joint include the guide bar of a guide rail. One of these pliers arms on the guide rail side has fixed friction member and the other is shaped as a pressure body, the one with the guide bar in the opposite direction gap narrowing to the direction of travel of the load handler forms. There is a between the pressure body and the guide web Brake wedge mounted, the latter in the guide bar in Normal operation is not affected. On the other side of the pincer joint generates a preloaded spring element Spreading force on the gun arms, which in normal operation acts a stop that the opening width of the gun arms limited.

If the load handler over-speeds up Speed limiter mechanism on the brake wedge, whereby this is relative to the safety gear moving guide bar comes into contact and from this by friction up to a stop in the narrowing Gap is drawn into it. The resulting clamping force spreads the tong arms on the guide rail, causing the preloaded spring element on the other side of the pliers is pressed. The preload force of this spring element now presses the friction member on the one hand via the tong arms as well as the pressure body and the brake wedge on the other hand the guide bar, which creates a braking force on the load handler arises.

To the braking force generated by this safety device adjust the circumstances that influence the braking process, d. H. always the same delay on the load handler To be able to reach the safety device designed as pliers on their spring element-side pliers arms Electromagnetic system, which in the event of emergency braking of the Counteracts spring force of the spring element and thereby the normal force acting on the brake wedge and thus the braking force reduced. The force effect of the lifting magnet system, or the size of the braking force reduction is determined by a current controller depending on the signal from a deceleration sensor regulated so that the load handler is always braked with the same deceleration.

Such safety gear has the disadvantage that it takes up a large installation space, in particular because that Electromagnetic system act on relatively long gun arms must be sufficient in order to withstand the large normal braking force To be able to influence the area. It also requires one elaborate electronic control device that is related to Functional safety places considerable demands. In order to this also works in the event of a power failure remains, an emergency power supply is also required.

The present invention has for its object a Propose safety gear that the load handler independent of different payloads in the load handler and other influences, such as that Condition and contamination of the braking surfaces, the current Speed and the ambient temperature, always with brakes the same delay.

The solution to the problem is given in the characterizing Part of claim 1 with regard to their essential features and in the following claims with regard to further advantageous training.

The safety device according to the invention has essential Advantages on. It is based on safety device technology that has been known for a long time and requires little more installation space than one conventional design. It does not require an electronic one Control device that meets high safety requirements must suffice and in the event of a power failure only with an emergency power supply is still functional. It's easy to understand to install and adjust. vibration problems due to control vibrations cannot occur. On large part of the existing conventional safety gear can be retrofitted with the components according to the invention become.

In an advantageous development of the invention Setup is the speed at which the chock in the narrowing gap between the pressure body and the guide rail penetrates throughout the path of penetration limited by a speed limiting device. This ensures that in case of emergency braking abrupt build-up of the total braking force and thus a correspondingly strong jerk on the load handler avoided becomes.

Preferably, there is the stroke limiting device which End ring stroke of the brake wedge depending on the deceleration of the load handler limited, from a hydraulic system. Great forces that occur in this context can be minimized with hydraulic means Master installation space.

The speed limiting device, which is the rate of penetration of the chock limited, realized with hydraulic means. A such a solution is reliable and easily adjustable.

In a particularly simple embodiment of the invention there is the aforementioned stroke limiting device for the brake wedge from a hydraulic cylinder with piston rod, one Hydraulic medium container and one arranged in between Control valve, with a deceleration sensor the control valve so that this affects the movement of the hydraulic cylinder and thus the further penetration of the brake wedge is blocked, as soon as and as long as the delay of the load handler exceeds a certain value.

Another advantageous development of the invention exists in that the deceleration sensor is one with the load handler movably connected weight body is by the deceleration of the load suspension device occurring inertia influences the control valve via a lever system. The inertia usually acts against one Spring, the spring constant of which depends on the inertia force determines the control valve stroke.

The weight body of the deceleration sensor is preferably slidable on a first arm of a two-armed lever arranged so that it can be set at which Deceleration of the load handler's inertia causes the second lever arm to control the control valve against the Spring action reversed.

It is convenient to use the speed limiting device to limit the rate of penetration of the brake wedge by realizing that an adjustable hydraulic Flow valve limits the flow of the hydraulic medium, the one that limits the depth of penetration of the brake wedge Hydraulic cylinder via the control valve to the hydraulic medium tank flows.

In a preferred embodiment, this is the rate of penetration of the brake wedge limiting valve as Orifice valve or designed as an adjustable flow control valve. Aperture valves have a temperature and viscosity of the hydraulic medium practically independent throttling effect. Flow control valves cause one of the existing pressure of the hydraulic medium independent, constant flow and thus ensure a constant rate of penetration the brake wedge.

In a further embodiment of the invention, the Deceleration sensor from one attached to the load handler Delay sensor, in which, for example, a strain gauge force sensor from the delay of the load handler resulting inertial force of a measuring body detected and an amplifier circuit that affects the Control valve actuated electromagnetically.

Another advantageous development of the invention exists in that the hydraulic medium tank acts as an accumulator is executed. In this way, the entire stroke and Speed limitation system for the brake wedge into one closed hydraulic system under slight overpressure. Air pockets in the air caused by vibrations Hydraulic medium and its contamination are therefore excluded, which guarantees maximum functional reliability of the system. In addition, the Hydraulic cylinder after a fall by the mentioned Overpressure instead of a compression spring.

In a preferred embodiment of the safety gear it has a single hydraulic block, all of which Contains connecting lines of the hydraulic system, wherein all other components of the hydraulic system either are integrated in or attached to this block.

Fig. 1

zeigt schematisch ein Beispiel einer Einbausituation der erfindungsgemässen Fangvorrichtung in einer Aufzugsanlage.

Fig. 2

zeigt in schematischer Darstellung die erfindungsgemässe Fangvorrichtung mit einem Bremskeil pro Führungsschiene und mit offenem Hydraulikmedium-Behälter.

Fig. 3

zeigt eine Variante der Fangvorrichtung mit zwei Bremskeilen pro Führungsschiene, mit einem Druckspeicher als Hydraulikmedium-Behälter und mit einer elektrischen Ansteuerung des Steuerventils.

Embodiments of the invention are shown in FIGS. 1 to 3 and explained in more detail in the following description.

Fig. 1

schematically shows an example of an installation situation of the safety device according to the invention in an elevator system.

Fig. 2

shows a schematic representation of the safety device according to the invention with a brake wedge per guide rail and with an open hydraulic medium container.

Fig. 3

shows a variant of the safety gear with two brake wedges per guide rail, with a pressure accumulator as a hydraulic medium container and with an electrical control of the control valve.

1 shows an elevator installation with its most important components. Two guide rails 1, a load suspension device, can be seen 2, with guide shoes 7 on the guide rails 1 is guided, a drive unit 3, a balance weight 4, suspension cables 5, an elevator speed limiter 6 with a limiter rope 11 as well two safety devices 8 according to the invention with a release lever 9 and a trigger connecting element 10.

In the event of emergency braking, the elevator speed limiter blocks 6 a limiter rope 11, which via the release lever 9 and the release connecting element 10 the two safety devices 8 triggers, causing the load handling device 2 is braked.

2, a safety catch device 8 according to the invention is closed recognize whose housing 15 the web of a guide rail 1st encompasses and has a brake wedge 13 which in one narrowing gap between a pressure body 14 and the web the guide rail 1 protrudes. The pressure body 14 is compared to the housing 15 of the safety gear via spring elements 16 supported. The arrow 17 is a symbol for one Trigger mechanism not shown here, which at Overspeed of the load handler 2 by the Elevator speed limiter 6 via limiter rope 11 and Release lever 9 is activated and the brake wedge 13 in the mentioned narrowing gap leads into it. The chock 13 thereby comes into contact with the relative to the safety gear moving guide rail 1 and is by the latter pulled into the narrowing gap, since the Contact surface between the brake wedge 13 and pressure body 14 through Coating or roller bearings are particularly low-friction is. As a result of the wedge effect, the brake wedge 13 is displaced the pressure body 14 against the spring elements 16, which thereby to build a pressure force. These press over the pressure hull 14 the brake wedge 13 against the guide rail 1, which is on it supports encompassing housing 15 of the safety gear. The resulting friction between the guide rail 1 and the brake wedge 13 and between the guide rail 1 and the housing 15, acts as a braking force on the load suspension device 2 out. The size of this braking force is proportional to the depth of penetration of the brake wedge 13 in the narrowing Gap, since the spring elements 16 are proportional to the depth of penetration be compressed. This depth of penetration is in the inventive Safety gear through a variable stop determined, according to the invention by a hydraulic cylinder 18 is formed with piston rod 19. The piston rod 19th of the hydraulic cylinder 18 facing away from the cylinder chamber a flow control valve 20 and a control valve 21 with a hydraulic medium tank 22 connected, these connections as pressure-resistant piping or as connections within of a hydraulic block can be executed. The flow valve 20 is available as an orifice valve or as a flow control valve with a check valve executed and has the task of draining the To influence hydraulic medium from the hydraulic cylinder 18 so that the brake wedge 13 with a controlled case Speed pulled into the narrowing gap is, so that the jerk occurring at the load handling device 2 is reduced at the start of braking. A version of the flow valve 20 as a flow control valve has the advantage that the flow of the hydraulic medium regardless of the pressure conditions is kept constant. The control valve 21 has the Task, when actuating the drain of the hydraulic medium to interrupt the hydraulic cylinder 18, the actuation done by a delay sensor 23. This contains a weight body 24 which is slidable on the horizontal Leg of an articulated angle lever 25 is attached, the bearing 26 in mechanical Connection to the load handler 2 is established. In case of delay of the load handler 2 from downward movement causes Inertia of the weight body 24 in the angle lever 25 torque proportional to the delay around its storage 26. The other leg of the angle lever 25 acts with one corresponding force on an actuating element 27 of the control valve 21, being the counterforce of a spring 28 has overcome that the actuator 27 in position tries to keep the passage position of the control valve 21 corresponds. The displaceability of the weight body 24 on the angle lever 25 allows the switching point of Set control valve 21 to different delay values. To avoid vibration problems during braking avoid, the movement of the bell crank 25 by a adjustable hydraulic attenuator 29 damped.

Safety braking with the safety device according to the invention proceeds as follows:
The trigger mechanism (arrow 17) raises the brake wedge 13 until it is clamped in the narrowing gap between the pressure body 14 and the guide rail 1. Due to the above-mentioned design measures, the friction between the brake wedge 13 and the guide rail 1 is higher than between the brake wedge 13 and the pressure body 14, which has the consequence that the guide rail 1 moving relative to the safety gear pulls the brake wedge 13 into the narrowing gap, the Brake wedge 13 simultaneously moves the piston rod 19 of the hydraulic cylinder 18 upward and thereby displaces the hydraulic medium located in the hydraulic cylinder 18 via the flow valve 20 and the open control valve 21 to the hydraulic medium container 22. The flow valve 20 ensures a controlled rate of penetration of the brake wedge 13.
As described above, this process produces a braking force which is proportional to the depth of penetration of the brake wedge 13 and acts on the load-carrying means 2. If the deceleration of the load-carrying device 2 now reaches a certain value during the penetration of the brake wedge, the deceleration sensor 23 set to this value reacts by the inertial force of the weight body 24, via the angle lever 25, bringing the control valve 21 against the spring 28 into the locked state. This prevents further penetration of the brake wedge 13 and an undesirably high deceleration of the load-carrying means 2. Should the deceleration of the load-carrying device 2 fall below the set value during the braking process, the deceleration sensor 23 would release the flow through the control valve 21 again and would allow the brake wedge to penetrate deeper until the set deceleration value was reached again.
To reset the safety gear into the initial state after safety braking, the load handler is moved in the opposite direction to the safety direction. The brake wedges move out of the narrowing gap, and the hydraulic cylinder 18 is brought into its starting position by a return spring 30, the hydraulic medium flowing back from the higher-lying hydraulic medium container 22 via the control valve 21 and the check valve of the flow control valve 20 and the corresponding Fills the piston chamber again.

3 shows a variant of the safety device according to the invention with two brake wedges 13. This variant has opposite 2 the advantage that the housing 15.1 no traverse movement to compensate for the im Operation required air gap 30, Fig.2 between the Execute housing 15, (Fig.2) and the guide rail 1 Has. Controlling the rate of penetration of the brake wedges 13 Hydraulic cylinder 18.1 acts here via Bridge element 31 synchronously on both brake wedges 13.

In Fig. 3, the hydraulic medium tank 22, (Fig.2) is the 2 replaced by a pressure accumulator 32, making the hydraulic system perfect against the environment completed and against air inclusion and pollution is protected. The one that creates a slight overpressure Pressure accumulator 32 also provides for the resetting of the Hydraulic cylinder 18.1 after emergency braking.

An electromagnetic one is also shown in FIG. 3 Variant for controlling the control valve 21.1. It contains a delay sensor 23.1, which acts as an integrated unit a force measuring device based on strain gauges has the inertial force of a weight body detected and an electrical signal to an amplifier and Switch unit 33 generates, which in turn on the actuating electromagnet 34 of the control valve 21.1 acts.

The main functions and effects of this safety gear variant correspond to those of the variant according to Fig. 2.

Adapted accordingly, the safety device according to the invention of course also as a safety brake to secure the Load handler 2 against overspeed in the upward direction be used.

Claims (12)

Safety gear with deceleration-dependent braking force, for a load handler of an elevator, which is triggered by an elevator speed limiter (6) when the load handler overspeeds, at least one brake wedge (13) in a narrowing gap between a spring-loaded pressure element (14) and a guide rail (1) of the load suspension device penetrates and thereby generates a braking force and the magnitude of this braking force depends on the deceleration occurring on the load suspension device,
characterized in that
the safety gear has a stroke limiting device (18, 18.1) which limits the end ring stroke of the at least one brake wedge (13) as a function of the deceleration of the load suspension means (2). Safety gear according to Claim 1, characterized in that it has a speed limiting device which adjustably determines the speed of the brake wedge (13) during its penetration stroke. Safety gear according to claim 1, characterized in that the stroke limiting device, which limits the end ring stroke of the brake wedge (13) as a function of the deceleration of the load-carrying means (2), is a hydraulic system influenced by a deceleration sensor (23). Safety gear according to claim 2, characterized in that the speed limiting device, which determines the speed of the penetration stroke of the brake wedge (13), is a hydraulic system. Safety gear according to claim 3, characterized in that the hydraulic system has a hydraulic medium container (22) and a hydraulic cylinder (18, 18.1) which limits the penetration stroke of the brake wedge (13) with its piston rod (19) and which is controlled via a control valve (21, 21.1) are connected to each other, as well as a deceleration sensor (23, 23.1), which, as soon as and as long as a certain deceleration of the load handler (2) is exceeded, influences the control valve (21, 21.1) in such a way that it controls the hydraulic cylinder (18, 18.1) blocked and thus prevents further penetration of the at least one brake wedge. Safety gear according to claim 5, characterized in that the deceleration sensor (23) has a weight body (24) which is movably connected to the load-carrying means (2) and which influences the control valve (21) via a lever system when the load-carrying means (2) is decelerated. Safety gear according to claim 6, characterized in that the weight body (24) of the deceleration sensor (23) is arranged displaceably on a first lever arm of a two-armed lever (25). Safety gear according to one of claims 5 to 7, characterized in that the speed limiting device includes the hydraulic cylinder (18, 18.1) which limits the penetration stroke of the brake wedge (13) and an adjustable hydraulic flow valve (20), the latter the flow of the hydraulic medium from the hydraulic cylinder (18 , 18.1) via the control valve (21, 21.1) to the hydraulic medium tank (22, 32). Safety gear according to claim 8, characterized in that the adjustable hydraulic flow valve (20) is an orifice valve or a flow control valve. Safety gear according to claim 5, characterized in that the deceleration sensor (23.1) is a device which contains a mechanical-electronic force sensor which detects the inertial force of a measuring body which occurs during deceleration, and which controls the control valve (21.1) via an electronic amplifier circuit (33). actuated by means of an electromagnet (34). Safety gear according to claim 5, characterized in that the hydraulic medium container is a pressure accumulator (32). Safety gear according to one of claims 3 to 11, characterized in that a single hydraulic block per safety gear contains all the connecting lines of the hydraulic system and all other hydraulic components are either integrated into this block or attached to it.

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