DE4006505A1 - Drive arrangement for DC motor with series current sensor - generates detect signal if sensor signal fails to maintain capacitor charge - Google Patents

Abstract

The driving arrangement feeds the current sensor's measurement parameter (UM) via an analogue monitoring device (U") which compares the measurement parameter with a first reference parameter (Uref1). If the reference parameter is exceeded, a first capacitor (C1) is charged but is discharged if the reference parameter is not exceeded. If the capacitor voltage falls below a signalling threshold a signal is generated. USE/ADVANTAGE - Signals detected defect in d.c. motor using simple, cost-effective technique.

Description

The invention relates to a device for operating a DC motor with one in series, one measuring current sensor.

DC motors are used, for example, as a fan motor ren used for cooling electrical assemblies. A for example, a malfunction caused by a short circuit the fan motor can cause a module to fail and there with too serious and costly damage ren. Therefore is a facility for operating the same current motor required, for example with the help detect a fault in a monitoring device and should signal. Such a malfunction can, for. B. due to a short circuit or overload of the fan motor tors or due to insufficient operating voltage of the fan termotors are caused.

The invention has for its object a Einrich tion of the type mentioned at the beginning with which simple and inexpensive way to disrupt the DC motor can be signaled.

This task is ge at a facility of the beginning named type solved in that the measured quantity of an analog working monitoring device is supplied, the a comparison of the measured variable with a first reference carries out size, whereby if it is exceeded, an er most capacitor charged and when they fall below is discharged and when one of the first condensate drops Tor tapped voltage under a signaling threshold signaling occurs.  

The reference size is specified so that the Im pulse peaks of the measured variable the first reference variable in the nor painting operation of the DC motor and there is charged by the first capacitor, while at The first capacitor falls below the reference value is slowly discharged again. In the event of a fault, d. H. at for example, when the DC motor is short-circuited, successfully no more pulse peaks of the measured variable. This will the first capacitor is not recharged and the one on it Most tappable capacitor voltage drops below the Si signaling threshold and there may be signaling consequences. Such a monitoring device can ko inexpensively set up from commercially available analog components builds, so that an expensive, especially from di gital components, monitoring device can be omitted.

In an advantageous embodiment, the measurement size on the non-inverting input of a first Operational amplifier switched, invert at its the input is the first reference, with the Output of the first operational amplifier a first Dio de in series with a first resistor and with a Pa parallel connection from a first capacitor and from egg Nem second resistor is connected. The leads first operational amplifier with the comparison of the measured variable the first reference size. When exceeding the the first reference quantity is the first capacitor over the first diode and the first resistor charged while when falling below the first capacitor over the second resistor is discharged very slowly so that in Normal operation, the chip that can be picked up at the first capacitor voltage does not fall below the signaling threshold. in the In the event of a fault, the pulse no longer occurs large, causing the first capacitor to stop charging  and thus the voltage on the first capacitor the Si below the signaling threshold. Such one Monitoring device is simple and inexpensive built analog components and enables a reliable monitoring of the operating status of the DC motor.

In one embodiment, the Monitoring device delayed. So that a un intended response of the monitoring device be avoided when switching on the DC motor.

In another embodiment, the Stromsen is sor in series with the switching path of a transistor where by means of the measurable variable which can be tapped at the current sensor a current limiting circuit drive the transistor ert that when the second reference value is exceeded the current flowing through the transistor is limited. Here the current sensor is used for both the current limiting circuit as well as for the monitoring device ver turns. This combination of the current sensor turns on simple and inexpensive way a reliable Current limitation and monitoring of the direct current motors realized.

In one embodiment, it is parallel to the current sor a third resistor in series with a second Capacitor, their common tap on the in vertizing input of a second operational amplifier is switched, at whose non-inverting input the second reference quantity is present, and the output of the second Operational amplifier is through a fourth resistor in series with a second diode to the control electrode of the transistor connected. The second op a comparison of the measured variable with the  second reference variable. Exceeds in fault case, d. H. for example in the event of a short circuit of the equal current motor, the measured variable the second reference variable, so this leads to a change in the control voltage of the Tran sistors and thus to limit the transistor current mes and thus to a limitation of the by the same current motor flowing current. This is especially so advantageous if two DC motors on one output voltage can be operated simultaneously, so that in Failure of one DC motor the other can remain in operation undisturbed.

In a further embodiment, the an optical voltage that can be tapped at the first capacitor and / or controlled acoustic signal element. In order to In the event of a fault, the responsible maintenance or loading operating personnel the failure of the DC motor be shown.

In one embodiment, the DC motor is designed as a fan motor. A combination of electricity limiting circuit and monitoring device in one common current sensor is particularly advantageous because in the event of a fan motor malfunction for cooling serious damage to individual components Assemblies can be prevented.

In a further embodiment, in particular for cooling a single electrical assembly two Fan motors provided, each a separate one Current limiting circuit and a separate monitoring have facility. Through the redundancy of a fan motors each with their own current limiting circuit and Monitoring device ensures that in the fault case of one fan motor the other in loading  can remain driven and the cooling of an assembly si created while signaling a fault maintenance of the other fan motor can initiate repair measures.

In the following the invention based on the in the figure illustrated embodiment explained in more detail.

The figure shows a device for operating a DC motor with a monitoring device and a current limiting circuit.

The figure shows a DC motor M, which is in series with the switching path of a transistor T and a current sensor designed as a measuring resistor RM. At the measuring resistor RM, a measured variable can be tapped in the form of a measuring voltage UM which controls the transistor T by means of a current limiting circuit S. For this purpose, the current limiting circuit S is connected to the terminals of the measuring resistor RM, and the control electrode (gate) of the transistor T T. Parallel to the series connection from the DC motor M from the switching path of the transistor T and from the measuring resistor RM is a reference potential (ground) related DC input voltage UE. The terminals of the measuring resistor RM are also connected to a monitoring device Ü, at the output of which a monitoring signal UA can be tapped. Parallel to the current measuring resistor RM is a third opposing stand R 3 in series with a second capacitor C 2 , whose measured tap is connected to the inverting input of a second operational amplifier OP 2 . At the non-inverting input of the second operational amplifier OP 2 there is a second reference variable in the form of a second reference voltage Uref 2 . The output of the second operational amplifier OP 2 is connected via a fourth resistor R 4 in series with a second diode D 2 to the control electrode of the transistor T. Between the control electrode of the transistor T and the ground potential is a third Dio de D 3 designed as a Zener diode, while a fifth resistor R 5 is switched on between the gate of the transistor T and the positive pole of the input DC voltage UE. The source electrode of the transistor T is also connected via a RC element formed from a resistor R and a capacitor C to the non-inverting input of a first operational amplifier OP 1 . At the inverting input of the first operational amplifier OP 1 there is a he reference voltage Uref 1 . The output of the first operational amplifier OP 1 is connected in series from a first diode D 1 , a first resistor R 1 and a parallel circuit from a first capacitor C 1 and a second resistor R 2 to ground potential. A voltage UA can be tapped from the parallel circuit comprising the first capacitor C 1 and the second resistor R 2 .

In the embodiment shown in the figure, the measurement voltage UM is tapped at the measurement resistor RM in accordance with the current flowing through the DC motor M. In normal operation, that is, if no disturbance occurs, for example in the form of a short circuit on the DC motor M, the transistor T is conductive and only the operating current of the DC motor M flows through the measuring resistor RM. The current flowing through the measuring resistor RM of the direct current motor M and thus also the measuring voltage UM have the temporal course of individual pulses which are repeated with a constant period. With the help of the fifth counter R 5 and the third diode D 3 the control voltage of the transistor T is given the control voltage so that the transistor T is in normal operation in the current state. The second reference voltage Uref 2 is predetermined accordingly. In the event of a fault, that is to say, for example, in the event of a short circuit in the direct current motor M, a high current flows through the measuring resistor RM, which likewise results in an increased measuring voltage UM. As a result, the predetermined voltage is exceeded by the second reference voltage Uref 2 of the second operational amplifier OP 2 . This leads to a change in the control voltage of the transistor T and thus to a limitation of the current through the direct current motor M. The current limiting circuit S works as a current control and causes a slow start-up of the direct current motor M, so that interference pulses are avoided. In the exemplary embodiment shown in the figure, the DC motor M is operated at the input DC voltage UE. However, the solution according to the invention can also be used when the DC motor M is fed from an AC or three-phase source. In this case, only a rectifier needs to be connected upstream.

The measuring voltage UM serves in the embodiment shown in the figure at the same time the evaluation by the monitoring device Ü. This should monitor the operating status of the DC motor and signal a fault in the event of a fault in the form of a monitoring signal UA. In the exemplary embodiment shown in the figure, the measuring voltage UM is removed via the RC element R, C. This causes a time-delayed switching of the monitoring device Ü, so that an unintentional response of the supervising device Ü is avoided when the DC motor M is switched on. The first reference voltage Uref 1 of the first operational amplifier OP 1 is specified so that it is exceeded with each current pulse of the DC motor and thus also with each pulse of the measurement voltage UM. As a result, the first capacitor C 1 is charged at the output of the first operational amplifier OP 1 via the first diode D 1 and the first resistor R 1 . Within the time after the decay of the pulse and the next new pulse, the first capacitor C 1 is discharged very slowly via the second resistor R 2 so that the normal voltage on the first capacitor C 1 voltage UA does not fall below a signaling threshold . In the event of a fault, however, that is, for example, when the DC motor M is short-circuited, there are no more pulses of the measuring voltage UM, or if the DC motor M is overloaded or the input voltage UE is too low for the DC motor M, the period between the individual pulses increases. The result of this is that, in the first case, the first capacitor C 1 is no longer charged and the voltage of the monitoring signal UA therefore drops below the evaluation threshold, or in the second case the first capacitor C 1 is discharged to such an extent that the signaling threshold is also fallen below. In this case, signaling can take place with the aid of an optical and / or acoustic signal element.

The simultaneous evaluation of the measuring voltage UM by means of the current limiting device S as well as the analog tendency monitoring device Ü thus enables simple space-saving and inexpensive switching without that complex, especially digital evaluation gene are needed.

Claims (8)

1. Device for operating a DC motor with a series, a measured variable supplying current sensor, characterized in that the measured variable (UM) is fed to an analog monitoring device (Ü) which compares the measured variable (UM) with a first Performs reference variable (Uref 1 ), a first capacitor (C 1 ) being charged when it is exceeded and discharged when it is undershot, and signaling when a voltage (U 1 ) that can be tapped at the first capacitor (C 1 ) drops below a signaling threshold he follows. 2. Device according to claim 1, characterized in that the measured variable (UM) is connected to the non-inverting input of a first operational amplifier (OP 1 ), at the inverting input of which the first reference variable (Uref 1 ) is located, with the output of the first Operation amplifier (OP 1 ) a first diode (D 1 ) in series with a first resistor (R 1 ) and with a parallel circuit of the first capacitor (C 1 ) and a second resistor (R 2 ) is connected. 3. Device according to one of claims 1 or 2, characterized, that the connection of the monitoring device (Ü) time delayed.   4. Device according to one of claims 1 to 3, characterized in that the current sensor (RM) is in series with the switching path of a transistor (T), the sensor at the current sensor (RM) tapped measurable variable (UM) by means of a current limiting circuit (S) controls the transistor (T) so that when a second reference size (Uref 2 ) is exceeded, the current flowing through the transistor (T) is limited. 5. Device according to one of claims 1 to 4, characterized in that parallel to the current sensor (RM) was a third opponent (R 3 ) in series with a second capacitor (C 2 ), their common tap on the inverting input a second operational amplifier (OP 2 ) is connected, at the non-inverting input of which the second reference variable (Uref 2 ) is present, and that the output of the second operational amplifier (OP 2 ) is connected in series with a second diode (R 4 ) via a fourth resistor (R 4 ) ( D 2 ) is connected to the control electrode of the transistor (T). 6. Device according to one of claims 1 to 5, characterized, that with the help of the tapped on the first capacitor Voltage (UA) an optical and / or acoustic signal element is controlled. 7. Device according to one of claims 1 to 6, characterized, that the DC motor (M) is designed as a fan motor is.   8. Device according to one of claims 1 to 7, characterized, that in particular for cooling a single electrical Assembly two fan motors (M) are provided, the each have a separate current limiting circuit (S) and Have monitoring device (Ü).