The present application hereby claims priority under 35 U.S.C. ยง119 on German patent publication No. 10154795.1 filed Nov. 8, 2001, the entire contents of which are hereby incorporated herein by reference.
The invention generally relates to a method and an apparatus for reducing the switching noise of an electromagnetic switching device.
A method and an apparatus are used in areas in which switching noise from an electromagnetic switching device, for example in the case of a control cubicle which is fitted to an elevator cabin and has contactors, is found by the passengers in the elevator cabin to be a disturbing side effect.
An embodiment of the invention may be based on an object of reducing switching noise during operation of an electromagnetic switching device, with little complexity.
The reduction in the switching noise of an electromagnetic switching device to which voltage is applied, as can be achieved by an embodiment of the invention, may be achieved with regard to the method and with regard to the apparatus in that, in contrast to a conventional way of acting on the coil in a switching device such as this, this coil is not driven with the entire value of the supply voltage, since this would lead to undesirable switching noises. In fact, the supply voltage may be reduced to a value which is just sufficient for movement of the armature. The increase to the total value of the supply voltage may then be used essentially only also to ensure sufficient subsequent mutual application of pressure between the moving and the stationary switching contacts. The time at which the supply voltage is increased from the reduced value to the total value can be determined by use of a simple timer, in particular in the form an RC element.
The method can advantageously be used firstly, in the same way as the apparatus as well, to reduce the switching noise and secondly in a conveyor system, in particular in an elevator system.
The invention as well as advantageous refinements as claimed in the features of the dependent claims will be explained in more detail in the following text on the basis of the exemplary embodiments which are illustrated schematically in the drawings, in which:
The first minimum value US MIN1 and the second minimum value US MIN2 of the supply voltage, which are correlated with the first contact movement SK1 and with the second contact movement SK2, respectively, are major parameters of a method embodiment for reducing the switching noise of an electromagnetic switching device 1. In this case, the electromagnetic switching device 1 has a coil 2, a moving armature 3 as well as moving and stationary switching contacts 4 and 5, as shown in FIG. 2.
The method embodiment results in a reduction in the switching noise in the electromagnetic switching device 1, which is driven with the supply voltage US, such that first of all, a first minimum value US MIN1 of the supply voltage US is defined which is sufficient at least for moving the armature 3 with the moving switching contacts 4, and the coil 2 and hence the armature 3 are then driven with the moving switching contacts 4 by the first minimum value US MIN1 of the supply voltage US at least until contact is made. The supply voltage US is then increased from the first minimum value US MIN1 to a second minimum value US MIN2 in comparison thereto such that the moving switching contacts 4 are moved with the stationary switching contacts 5 into sufficient mutual contact with pressure applied.
The sufficient mutual contact with pressure applied on the basis of the coil 2 being driven with the first minimum value US MIN1 and subsequently being driven with a time delay, by the second minimum value US MIN2 of the supply voltage US can, depending on the type and embodiment variant of the electromagnetic switching device 1, be carried out firstly in the case of rigid switching contacts 4, 5 even after the first contact movement SK1. Secondly, in the case of sprung switching contacts 4, 5, it may be carried out in the course of the movement between the first and the second contact movement SK1 and SK2.
The supply voltage US is increased from the first minimum value US MIN1 to the second minimum value US MIN2 as a function of time, with approximately 0.75 to 0.95 times, in particular 0.9 times, the second minimum value US MIN2 being defined for the first minimum value US MIN1. The method for reducing the switching noise of an electromagnetic switching device is suitable, inter alia, for use in a conveyor system, in particular in an elevator system.
The apparatus 6 is provided with a drive unit 7 and with a voltage control unit 8. The drive unit 7 is used to drive the voltage control unit 8 as a function of time. The voltage control unit 8 allows the supply voltage US for the coil 2 and accordingly for the movement of the armature 3 with the moving switching contacts 4 to be fixed at least at the sufficient first minimum value US MIN1. The first minimum value US MIN1 of the supply voltage US is used for making contact.
Initiated by a time-delayed drive pulse to the drive unit 7, the supply voltage US is then increased via the voltage control unit 8 to a second minimum value US MIN2, such that the switching contacts 4, 5 can be moved into mutual contact, thus ensuring that sufficient pressure is applied. The first minimum value US MIN1 is in this case approximately fixed at 0.75 to 0.95 times, in particular at 0.9 times, the second minimum value US MIN2.
The drive unit 7 has a timer 9 in the form of a capacitor C, which is provided in order to determine the time at which the supply voltage US is increased from the first minimum value US MIN1 to the second minimum value US MIN2. A switching element 10 in the form of an optocoupler OC, which is used for driving a voltage limiter 11, is also provided, inter alia, as part of the drive unit 7. The voltage control unit 8 is driven by the drive unit 7 as a function of switching via the switching element 10. The switching element 10 may also be provided in the voltage control unit 8, in an alternative embodiment variant.
The voltage control unit 8 also has the voltage limiter 11 in the form of a zener diode Z, which is provided for limiting the supply voltage US to the first minimum value US MIN1, for allowing the supply voltage to rise to the second minimum value US MIN2 and for driving an actuating element 12, which is arranged in the voltage control unit 8. In an alternative embodiment variant, the voltage limiter 11 may also be arranged in the drive unit 7. The actuating element 12 is in the form of a transistor T and is in this case used for driving the coil 2, whose actuating input is connected to a first resistor R1, which is likewise arranged in the voltage control unit 8. The timer 9 is reset by means of a reset element 13, which is part of the drive unit 7.
The reset element 13 in this case comprises a diode D and a second resistor R2, which is connected in series with it. The second resistor R2, which is arranged in the reset element 13, in this case interacts with the parallel-connected capacitor C, which is used as the timer 9, in the form of an RC element. The optocoupler OC comprises a phototransistor FT and a photodiode FD, which are arranged in series with the capacitor C and with the diode D. The phototransistor FT is connected by one of its zones to the zener diode ZD, which is itself connected in series with the first resistor R1 and with the actuating input of the transistor T. Finally, the transistor T is electrically conductively connected from one of its zones to the coil 2.
The voltage supply for the apparatus 6 is provided, purely by way of example, by a rectifier module 14, which if required may be fed with direct current or alternating current, and/or by an electronic supply module 15, which is used for rectification and for smoothing the supply voltage US.
The supply voltage US is passed via the rectifier module 14 to the electronic supply module 15, which supplies voltage to the photodiode FD in the optocoupler OC, which drives the phototransistor FT by use of a light signal. The phototransistor FT is switched on and its resistance becomes low, so that the zener diode Z has voltage applied to it. Further, in this case, the zener voltage, which corresponds to the first minimum value of the supply voltage US MIN1, that is to say approximately 0.9 US, across this zener diode Z collapses. The coil 2 of the electromagnetic switching device 1 is then driven using the first resistor R1 via the transistor T. In the course of the first contact movement SK1, the moving switching contacts 4 make contact with the stationary switching contacts 5.
At the same time that the phototransistor FT is driven, voltage is supplied to the capacitor C via the photodiode FD. In consequence, the latter starts to charge, as a function of time, up to the level of the supply voltage US and, on reaching this level, starts to act on the optocoupler OC. The photodiode FD in consequence no longer emits any light signal to the phototransistor FT, as a result of which this now has a high impedance. The zener diode Z is no longer driven, so that the voltage drop amounting to the zener voltage no longer exists. The transistor T is in consequence fully switched on, resulting in the higher, second minimum value of the supply voltage US MIN2 being applied to the coil 2. The moving and the stationary switching contacts 4 and 5, respectively, in this case make the sufficient mutual contact SK P2 with pressure applied. Provided the supply voltage US is switched off, the timer 9 is reset by the capacitor C discharging via the diode D to the second resistor R2.
The apparatus 6, which is easy to fit and if appropriate to retrofit, for reducing the switching noise of an electromagnetic switching device 1, for example in the form of a contactor or of a relay, is suitable inter alia for use in a conveyor system, in particular in an elevator system. The level of the respective supply voltage US is in this case a measure of the magnitude of the switching noise. Normal values for the supply voltage for DC contactors are approximately between 24 V and 110 V; for AC contactors these values are approximately between 110 V and 230 V. In the case of a DC contactor which is driven at approximately 90% of the original supply voltage US, which may, for example, be between 85 V and 110 V, the switching-on noise is reduced by about 6 dB. There is thus no need for complex and costly silencing measures.
An embodiment of the invention can be summarized as follows: In order to achieve a reduction in the switching noise during operation of an electromagnetic switching device with little complexity, a coil 2 for moving an armature 3 with moving switching contacts 4 is driven in order to make contact at a first minimum value US MIN1 of a supply voltage US, with the supply voltage US being increased from the first minimum value US MIN1 to a second minimum value US MIN2 as a function of time such that the moving switching contacts 4 can be moved with the stationary switching contacts 5 into sufficient mutual contact with pressure applied.
The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims.
Number | Date | Country | Kind |
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101 54 795 | Nov 2001 | DE | national |
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Number | Date | Country | |
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20030164747 A1 | Sep 2003 | US |