DE102012112692A1 - Device and method for operating an electromagnetic switching device drive - Google Patents

Abstract

Device for operating an electromagnetic switching device drive with a pull-in coil, comprising a measuring transducer for generating a signal variable that corresponds to a magnetic flux of the pull-in coil, and a controller for setting a signal for actuating the pull-in coil during the pull-in process, and switching device, in particular a contactor, with an electromagnetic Switchgear drive, which has a pull-in coil, and a method for operating an electromagnetic switchgear drive with a pull-in coil, a signal variable corresponding to the magnetic flux of the pull-in coil being generated by a measuring transducer, and a signal for controlling the pull-in coil being set during the pull-in process by a controller.

Description

The invention relates to an apparatus for operating an electromagnetic switching device drive with a tightening coil, comprising a transducer for generating a signal magnitude corresponding to a magnetic flux of the tightening coil, and a controller for setting a signal for driving the tightening coil during the tightening operation, and a switching device, in particular Contactor, comprising an electromagnetic switching device drive having a tightening coil, and a method for operating an electromagnetic switching device drive with a tightening coil, wherein a signal corresponding to the magnetic flux of the attracting coil signal size is generated by a transducer, and by a controller, a signal for driving the Suiting coil is set during the tightening process.

In switching devices, such as power contactors with electromagnetic drive, a magnetic field is built in a switching operation in the drive, on the one hand is sufficiently strong to drive the drive mechanism, on the other hand, but not excessive, to avoid damage to the drive mechanism. Damage can arise, for example, when the magnetic field built up by a tightening coil during the tightening process is so strong that so-called contact bouncing occurs. In this case, a contact with high kinetic energy strikes his counter-contact and bounces back again. Depending on the kinetic energy, the contact bounce can repeat several times before finally establishing a permanent contact. This can damage the contacts mechanically. In addition, especially when switching high power during contact bouncing unwanted arcing, which can lead to a contact erosion.

From the US 2006/0171091 A1 is a regulation of the movement of an armature of an electromagnetic contactor drive depending on the anchor position known. The current armature position can be estimated by a processor based on the measurement of the magnetic flux of the tightening coil by means of a sensor coil. For estimation, the ratio of measured pull coil current to magnetic flux can be evaluated.

A control that only controls the magnetic flux in the drive is not able to respond to different power requirements of the drive through different strokes or mounting positions. The speeds of the mechanics of shooters vary considerably when the stroke is changed within the tolerance range. The installation position also influences the speed.

An object of the present invention is to propose an apparatus and / or a method for improved and / or less complex operation of an electromagnetic drive, whereby the speed fluctuations are reduced.

The object is solved by the subject matters of the independent claims. Further embodiments of the invention are the subject of the dependent claims.

The inventive apparatus for operating an electromagnetic switching device drive with a tightening coil has a transducer for generating a signal magnitude corresponding to a magnetic flux of the tightening coil, and a controller for setting a signal for driving the tightening coil during the tightening operation in response to a control difference from a reference variable and the signal size. The reference variable preferably predetermines a determined nominal value course of the magnetic flux of the tightening coil during the tightening process. An advantage of this control is that independence of input voltage and temperature of the switching device drive is achieved. Furthermore, a control for monitoring the control and for adjusting the reference variable in response to a change in the signal for driving the tightening coil during the tightening operation is provided according to the invention.

The advantage of the control is thus combined with the advantages of a control. By monitoring the control and adapting the reference variable function during the tightening process by means of a controller, the speed fluctuations caused by lifting tolerances and by a changed installation position are reduced and can not be compensated by the setpoint-controlled control. This increases the life of the main contacts.

Preferably, the transducer is provided for generating the signal magnitude based on an induction voltage generated in a coupled to the tightening coil measuring coil by the magnetic flux of the tightening coil in a tightening operation of the drive. An existing in the switching device holding coil can be advantageously used as a measuring coil. The terms holding coil and measuring coil are therefore used synonymously. Alternatively, a magnetic field sensor may be provided to measure the magnetic flux of the tightening coil.

The device according to the invention can be advantageously used in any switching device which is driven by means of electromagnets. The signal for driving the tightening coil is basically any suitable signal for driving tightening coils. Preferably, the signal is a pulse width modulated signal, wherein the controller is then provided for continuously setting a pulse width of the pulse width modulated signal. It is particularly preferred that the controller has a P controller, wherein the pulse width of the pulse width modulated signal is adjustable in proportion to the control difference.

The transducer and / or the controller are preferably implemented by a processor and a memory in which a program for calculating the signal magnitude based on the measured induction voltage, to form the control difference from the reference variable and the signal supplied to the processor signal magnitude and for regulating the signal is stored by the control difference. Further preferably, a program for monitoring the control is stored, which adjusts the reference variable in response to a change in the signal for driving the tightening coil.

Another object of the invention is a switching device, in particular a contactor, with an electromagnetic switching device drive, which has a tightening coil, wherein a device according to the invention for the operation of the electromagnetic switching device drive is provided.

Another object of the invention is a method for operating an electromagnetic switching device drive with a tightening coil, wherein a signal corresponding to the magnetic flux of the tightening coil signal size is generated by a transducer, and wherein a controller for a signal for driving the tightening coil during the tightening operation in response to a Control difference from a reference variable and the signal size is set. According to the invention it is further provided that the control is monitored by a controller, wherein the reference variable is adjusted in response to a change in the signal for driving the tightening coil. As an initial reference variable of the control, a previously determined setpoint course of the magnetic flux of the tightening coil during the tightening process is preferably used. The setpoint course is determined in particular as a function of the supply voltage of the drive and / or the temperature of the tightening coil.

The measuring transducer preferably measures an induction voltage generated in a measuring coil coupled to the tightening coil by the magnetic flux of the tightening coil during a tightening operation of the drive and sets the signal magnitude on the basis of the measured induction voltage.

The signal for driving the tightening coil is preferably a pulse width modulated signal, wherein the controller continuously adjusts a pulse width of the pulse width modulated signal. In particular, the controller has a P controller, wherein the pulse width of the pulse width modulated signal is set proportional to the control difference.

According to a preferred embodiment of the method it is provided that for monitoring the control by the controller, a first measurement of the signal is made at the beginning of a tightening process, at the first time the drive regardless of influencing factors, ie input voltage, temperature, mounting position and lifting tolerances not is in motion, and that a second measurement of the signal is made at a time after the first measurement, wherein the second time is chosen so that it is dependent on the factors influencing whether the drive is either not yet in motion, or already in Movement is. Further preferably, the values of the signal in the first measurement and in the second measurement are averaged over a period of time.

Further preferably, the measured value of the signal of the first measurement is compared with the measured value of the signal of the second measurement, and the ratio is used as a correction factor for adjusting the reference variable. Alternatively, it is provided to compare the measured value of the signal of the first measurement with the measured value of the signal of the second measurement and to use the ratio for adjusting the reference variable by selecting from a stored assignment table of ratio and reference variable.

Further advantages and possible applications of the present invention will become apparent from the following description in conjunction with the embodiments illustrated in the drawings.

Show it

1 a block diagram of an embodiment of an apparatus for operating an electromagnetic drive according to the invention;

2 a simplified circuit diagram of an embodiment of a contactor of high power, in which a device is integrated according to the invention.

In the following description, identical, functionally identical and functionally connected elements may be provided with the same reference numerals. Absolute values are given below by way of example only and are not to be construed as limiting the invention.

The 1 shows a block diagram of the device according to the invention, in particular for an electromagnetic drive of a contactor of high power. The contactor drive has a tightening coil 28 and a holding coil 26 on which a controlled system 12 form. The retaining coil is constructive 26 with the suit reel 28 coupled so that the same magnetic flux Φ acts in both coils. This raises over the holding coil 26 a voltage UHalt = -N · dΦ / dt when a magnetic flux Φ is generated by the tightening coil during the tightening operation. The voltage UHalt corresponds to an induced voltage UInd, which in 1 is designated as size x.

A transducer 14 calculates the time-dependent magnetic flux Φ (t) from the voltage magnitude x and outputs the calculated flux as the signal quantity wx.

A subtractor 18 subtracts the signal magnitude wx from a command value w, which specifies a setpoint course of the magnetic flux in the tightening coil during the tightening process. The setpoint curve was determined depending on various influences on the drive. For this, measurements of the magnetic flux characteristic in the tightening coil are carried out during various different influences on the contactor drive. Measurements can be made for different mounting positions of the contactor, at different supply voltages of the drive and / or at different temperatures. From the flux curves determined by the various measurements, a setpoint curve is then determined which is adapted to an optimum function of the drive under different operating conditions, in particular ensures optimum optimum function for different mounting positions, supply voltage and temperature ranges.

The subtractor 18 generated control difference xd becomes a controller 16 with a microprocessor 20 and an actuator 21 supplied to the pulse width of a pulse width modulated signal (PWM signal), wherein the controller 16 depending on the control difference xd and an input voltage Uin the pulse width of a pulse width modulated signal y for driving the tightening coil 28 established. The PWM signal y has a period T. During each period T, the signal y is turned on for the specified time, on-time, or on-time. The on-time corresponds to the pulse width of the signal y during each period T and determines that in the tightening coil 28 generated magnetic flux Φ (t), since with signal y on the suitor coil 28 is energized. The on-time is from the controller 16 depending on the control difference xd determined. Typically, a minimum and a maximum value are predetermined, which in extreme cases may have the values 0 and T, respectively. Between the minimum and the maximum value, the on-time can be set, for example, proportionally to xd. In this case, the controller implements 16 a P-controller, which converts the control difference xd proportional to the on-time. This regulation allows the magnetic flux of the tightening coil 28 be set very precisely and finely.

In contactor drive control, a method is used in which a reference variable w determines the behavior of the control. This reference variable w is optimized for a contactor which has the largest possible stroke. In this case, the controller is able to control different temperatures of the coil or different supply voltages Uein. However, he is unable to correct the influences from the mechanics to always use the optimum force. Mechanical influences can be, for example, manufacturing tolerances. Through this a contactor can also have smaller strokes. With a smaller stroke, a higher speed is measured during the contact closure or the armature core shock. The installation position also plays a role when it comes to the required force that must be applied by the contactor drive. The higher speeds result from higher accelerations and are directly related to the forces acting on the mechanics. An increase in the forces acting on the mechanism, in turn, has a negative impact on the life of the device. Therefore, according to the invention, the required power requirement is determined in the first phases of the tightening process and the reference variable function w is adjusted on the basis of the determined values.

The stored reference variable w is determined by applying a DC voltage, the so-called trip voltage. The magnetic flux is absorbed during the tightening process. The time course of the magnetic flux from the application of the voltage to the armature core shock is used as a reference variable w. This process preferably takes place at the largest possible stroke. Since this reference variable w is always used unchanged in the prior art methods, the same magnetic forces are always built up, although they are not always needed. This is the case, for example, when the contactor is not mounted on the wall but on a table. Then in addition to the magnetic forces and the acceleration of gravity acts on the drive.

Since the calibration, as described above, was carried out to determine the reference variable w with a specific trip voltage UTrip, the regulator must always set an equivalent voltage Uequi of the attraction coil by setting the PWM (variable y) 28 provide. If the ratios are equal to the ratios during calibration then UTrip ≡ Uequi = Uein · y. Now, if the required force is reduced, for example because the stroke has been reduced, then the upper equation becomes an inequality: UTrip> Uequi = Uein · y. This inequality results from the altered signal y, which is adjusted by the control to maintain the given magnetic flux. Thus, by evaluating the y values, it is possible to deduce the required power requirement.

The task of the scheme 16 It is during the tightening phase to make sure that in the suit coil 28 the predetermined magnetic flux is generated. Thus, the on-time must be from the regulator 16 be adjusted so that in the suit coil 28 With their ohmic resistance the magnetic flux can be built up. This process depends on the inductance of the tightening coil 28 and the resistance of the copper of the coil. The inductance LAnzug of the attraction coil is inversely proportional to the air gap and thus to the path s. The coil resistance Rcu depends on the temperature. If the temperature influence can be eliminated or is minimal, the behavior of the control is 16 only dependent on the air gap.

According to the invention, the scheme 16 through a controller 4 monitored, wherein the reference variable w in response to a change of the signal y for driving the tightening coil 28 is adjusted. To the influence of temperature on the controller 4 to exclude, is the beginning of the tightening process by the controller 4 with a monitoring 40 a measurement of the y-values made. In this case, the mean value of the y values is formed over a period of time. This value is proportional to the voltage Uäqui. In this determined value is determined by the scheme 16 a deviation, due to influences, such as temperature, etc. included. The deviation can be described mathematically by a factor. It is assumed that the deviations during a tightening process are constant. If the mean value of the values y of the signal is determined again at a later time during the tightening process, then this mean value also contains the same deviation.

A second measurement of the y-values by the monitoring 40 is performed at a time after the first measurement to which the drive is either not yet in motion, or has already started to move. The time of the second measurement is chosen so that at a high power requirement of the drive this is not yet in motion, while at a lower power requirement of the drive this will have already set in motion. In the event that the drive is not yet in motion, the measured values of the first measurement of the y values and the second measurement of the y values will be substantially equal. However, if the power requirement of the drive is lower, and the drive has already set in motion, then the air gap sAir is already reduced compared to its initial value at the time of the second measurement. As the air gap decreases, the inductance LAnz of the tightening coil increases 28 : LAnz (sAir) = Φ / Θ · (NAnz) ² = A · (μFe / sFe + μAir / sAir) · (NAnz) ² .

Now the controller is 16 react to this circumstance and reduce the PWM so as not to exceed the required magnetic flux: Θ = Φ controlled / LAnz (sAir) · (NAnz) ² = IAnz · NAnz, with IAnz ≈ Uein · y · f (t, x).

By the scheme 16 the magnetic flux Ф is given. If the inductance LAnz of the tightening coil increases 28 on, so the flooding Θ must be reduced. The flooding Θ is, as shown above, on the number of turns NAnz the suit coil 28 coupled with the exciting current IAnz and the voltage Uäqui. A function f (t, x) describing the shape of the reference variable w has a form of: f (t, x) = (1-exp (1-α (x) * t / L)) / α (x ). If the function f (t, x) deviates from the function during the calibration, this would have an effect on the magnetic flux Ф via the concatenation. Since the system is designed so that any change would increase the magnetic flux, the controller will respond 16 with a lowering of the PWM (y) to prevent this.

The method can also be started with the smallest guide curve w. Then, the second measurement must be made at a time when the drive with the smallest stroke must already be in motion, while the one with a larger stroke has not or only very slightly moved.

An evaluation 41 includes, for example, the two determined y-values yt1 and yt2 of the first measurement at time t1 and the second measurement at time t2 in the ratio: β = yt1 / yt2. This value β can be directly offset with the reference variable w and the regulation by the adaptation 42 be provided: wnew = w · β.

Should the available processor 20 do not provide enough performance, so may alternatively be different Management functions w will be deposited. Based on the ratio β, the appropriate function w can then be selected.

The 2 shows a schematic simplified circuit diagram of a contactor of high power with an implementation of the device according to the invention according to 1 through the scheme 16 with the microcontroller 20 (please refer 1 ). The contactor is usually connected via the two supply terminals A1 and A2 with an AC voltage. The contactor can hereby be designed to be supplied with an alternating voltage in a range of a few volts to several hundred volts. The voltage applied to the inputs A1 and A2 becomes a direct current (DC) voltage supply 30 fed, which usually includes a rectifier circuit. A first from the DC power supply 30 generated DC voltage is directly a suit coil 28 fed to the switching drive of the contactor. A second from the DC power supply 30 generated DC voltage is directly a holding coil 26 supplied to the switching drive. The suit coil 28 and the holding coil 26 are each via a FET (field effect transistor) 32 respectively. 34 can be connected to a reference potential, so that when the FET is turned on, the respective coil is energized and a magnetic flux is generated. During a switching operation, only the tightening coil is tightened 28 energized, whereby the switching drive is moved to close the switching contacts (not shown) of the contactor. When the switch contacts are closed, is switched to the holding operation, in which only the holding coil 26 is energized. Due to the structural design of the holding and tightening coil 26 respectively. 28 both are coupled in such a way that the same magnetic flux Φ flows in them when one of the two coils is energized. When tightening process is therefore in the holding coil 26 due to the suit coil 28 generated magnetic flux induced the voltage UInd. This voltage is UInd via a resistor network 24 , in particular a voltage divider, converted into a voltage for further processing an input of a microprocessor or controller of the control 16 is supplied. The microprocessor or controller of the controller 16 executes a stored in a (not shown) memory operating program of the contactor, which in principle the in the 1 shown regulation 16 implemented. The reference variable w for the control is as setpoint curve 22 of the magnetic flux Φ (t) stored during the tightening process and is used for the purposes of regulation 16 read. Through the scheme implemented by the operating program 16 generates the microprocessor or controller 20 the signal y to control the tightening coil FET 32 , The control 4 in turn monitors the signal y in the above with respect to 1 described manner and changes the setpoint course, if necessary 22 of the magnetic flux Φ (t) during the tightening process, ie the reference variable w for the control 16 , A corresponding operating program of the controller 4 can be executed by the same microprocessor as the program of the control 16 ,

To measure the magnetic flux, instead of the measuring coil 26 Alternatively, a magnetic sensor (not shown), such as a Hall sensor or GMR (Giant Magneto Resistance) may be provided.

With the present invention, the scheme 16 of the electromagnetic drive of a switching device by setting a defined magnetic flux Φ of the tightening coil 28 be generated by the electromagnetic drive, which can be achieved by the input voltage and temperature of the tightening coil almost independent behavior of the drive. The regulation 16 , which controls only the magnetic flux in the drive, but is not able to respond to different power needs of the drive at different strokes or mounting positions. Therefore, the advantage of the scheme 16 Independence of voltage and temperature of the system, with the advantages of control 4 combined by monitoring the scheme 16 and adjusting the reference variable function w during the tightening operation by the controller 4 is provided.

The invention can be applied in any switching device that is driven by means of electromagnets. For contactors of high performance, the use is particularly advantageous. The speed of the mechanics of contactors can vary considerably if the stroke is changed within the tolerance range. The installation position also influences the speed. By the control according to the invention 4 the speed fluctuations are reduced. Lower contact closure speeds minimize bounce. As a result, the contacts are less burdened and the life expectancy of the contacts increases. It may be possible to save expensive silver materials.

LIST OF REFERENCE NUMBERS

12

 Switchgear drive

14

 transducers

16

 regulator

18

 subtractor

20

 microcontroller

21

 Steller

22

 Stored setpoint course

24

 Resistor network

26

 holding coil

28

 pulling coil

30

 Direct current (DC) power supply

32

 Coils brake FET

34

 Suit coils FET

4

 control

40

 monitoring

41

 evaluation

42

 Adaptation

A1

 entrance

A2

 entrance

wx

 signal amplitude

w

 command variable

xd

 Control difference

x

 reading

y

 Signal for activation

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2006/0171091 A1 [0003]

Claims (10)

Device for operating an electromagnetic switching device drive ( 12 ) with a tightening coil ( 28 ), comprising a transducer ( 14 ; 24 ) for generating a signal magnitude (wx) corresponding to a magnetic flux of the attraction coil, and a regulator ( 16 ) for setting a signal (y) for driving the tightening coil during the tightening operation in response to a control difference (xd) from a reference variable (w) and the signal size (wx), wherein a controller ( 4 ) is provided for monitoring the control and for adjusting the reference variable (w) in response to a change in the signal (y) for driving the tightening coil during the tightening operation. Device according to Claim 1, characterized in that the signal (y) for activating the tightening coil is a pulse-width-modulated signal, the regulator ( 16 ) is provided for continuously setting a pulse width of the pulse width modulated signal. Device according to one of the preceding claims, characterized in that the reference variable (w) a determined setpoint course ( 22 ) of the magnetic flux of the tightening coil ( 28 ) during the tightening process. Switching device, in particular contactor, with an electromagnetic switching device drive ( 12 ), which has a suit reel ( 28 ), characterized in that a device for operating an electromagnetic switching device drive ( 12 ) is provided according to one of the preceding claims. Method for operating an electromagnetic switching device drive ( 12 ) with a tightening coil ( 28 ), whereby by a transducer ( 14 . 24 ) a signal magnitude (wx) corresponding to the magnetic flux of the pull-in coil is generated, and by a regulator ( 16 ) a signal (y) for driving the tightening coil during the tightening operation in response to a control difference (xd) from a reference variable (w) and the signal size (wx) is set, the control by a controller ( 4 ) and wherein the command variable (w) is adjusted in response to a change of the signal (y) for driving the tightening coil. A method according to claim 5, characterized in that by the transducer ( 14 ; 24 ) one in one with the suiting coil ( 28 ) coupled measuring coil ( 26 ) by the magnetic flux of the tightening coil ( 28 ) is measured during a tightening operation of the drive generated induction voltage (x) and the signal size (wx) is adjusted based on the measured induction voltage (x). Method according to one of claims 5 or 6, characterized in that a first measurement of the signal (y) is made at a first time at the beginning of a tightening operation, wherein at the first time the drive is not in motion independent of influencing variables, and that a second measurement of the signal (y) is made at a second time after the first measurement, wherein the second time is selected so that there is a function of the factors influencing whether the drive is not yet in motion or is already in motion. Method according to one of claims 5 to 7, characterized in that the values of the signal of the first measurement are compared with the values of the signal of the second measurement, the ratio being used as a correction factor for adapting the reference variable (w). Method according to one of claims 5 to 7, characterized in that the values of the signal of the first measurement are compared with the values of the signal of the second measurement, the ratio used for the adjustment of the reference variable by selection from a relationship table of ratio and reference variable becomes. Method according to one of claims 5 to 9, characterized in that the values of the signal in the first measurement and in the second measurement are averaged over a period of time.

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