EP2534752A2 - Method and control unit for determining the strength of a magnetization current for an asynchronous motor - Google Patents

Abstract

The invention relates to a method (300) for determining the strength of a magnetization current for an asynchronous motor. Said method (300) comprises a step, in which an individual characteristic curve (200) is provided (310) for the asynchronous motor (120), said curve representing the influence of a magnetization current on at least one winding of the asynchronous motor (120) for a predetermined magnetization current. The method (300) also comprises a step, in which the strength of the magnetization current is determined (320) to magnetize the asynchronous motor (120) using the individual characteristic curve (200) for said motor (120).

Description

 Method and control device for determining a strength of a magnetization current for an asynchronous motor The present invention relates to a method according to claim 1

Control device according to claim 9 and a computer program product according to claim 10.

In modern electric drive technology, asynchronous machines (also referred to as asynchronous motors) are often used because of the overwhelming advantages. However, these asynchronous machines require a partially difficult control, especially during commissioning, in particular, a sensorless due to the high efficiency of the market is particularly in demand. In order to operate an above-mentioned asynchronous machine, a magnetization of this motor or machine is required in advance. In the prior art concerning the electric drive technology and the detailed literature on this is never concretely on a particularly favorable choice of a particular

Amperage for an asynchronous machine type received. Neither theoretical nor practical reports for starting up an asynchronous machine allow a person skilled in the art the optimum current for the magnetization of these

Asynchronous machine to determine exactly. Furthermore, both university reports and field reports suggest only the use of a rule of thumb according to which a magnetizing current to be selected should correspond to approximately half the rated current of the asynchronous machine. However, it is overlooked that it is often in the choice of such a current for

CONFIRMATION COPY Magnetization of the asynchronous machine to a high heating (possibly also to a brief overheating) by Aufmagnetisierungsverluste and thus to a non-optimal power output during commissioning of the asynchronous machine comes. Other approaches to the physical determination of the operating point of an asynchronous motor are not known.

It is therefore the object of the present invention to provide an improved method and an improved controller for determining a strength of a

Magnetizing current of an induction motor to create. This object is achieved by a method according to claim 1, a control device according to claim 9 and a computer program product according to claim 10.

The present invention provides a method of determining a magnitude of a magnetizing current for an asynchronous motor, the method comprising the steps of:

 Providing an individual characteristic for the asynchronous motor representing a relationship of a magnetization flux for at least one winding of the asynchronous motor at a predetermined magnetizing current; and

Determining a magnitude of a magnetizing current for magnetizing the asynchronous motor using the individual characteristic for the

 Asynchronous motor.

The present invention also provides a control device which is adapted to the. To carry out or implement steps of the method according to the invention.

 In particular, the present invention provides a control apparatus for determining a

Strength of a magnetizing current of an asynchronous motor, the control device having the following features:

a memory unit, which is designed to provide an asynchronous motor-individual characteristic, wherein the characteristic is a connection of the Represents magnetization flux for a winding of the asynchronous motor at a predetermined magnetizing current; and

 a determining unit for determining a current of a

 Magnetizing the asynchronous motor using the

 Asynchronous motor-individual characteristic is formed.

Also by this Ausführurigsvariante the invention in the form of a control device, the object underlying the invention can be achieved quickly and efficiently.

In the present case, a control device can be understood to mean an electrical device which operates as a frequency converter and processes sensor or data signals and outputs control signals in dependence thereon. The control unit may have an interface, which may be formed in hardware and / or software. In the case of a hardware-based design, the interfaces can be part of a so-called system ASIC, for example, which contains various functions of the control unit. However, it is also possible that the interfaces have their own, integrated

Circuits are or at least partially consist of discrete components. In a software training, the interfaces may be software modules that are present, for example, on a microcontroller in addition to other software modules.

Also of advantage is a computer program product with program code, which is stored on a machine-readable carrier such as a semiconductor memory, a hard disk memory or an optical memory and is used to carry out the method according to one of the embodiments described above, when the program is executed on a control unit.

The present invention is based on the finding that now on the basis of an individual characteristic curve for the magnetization behavior of the asynchronous motor (that is, the asynchronous machine), a very effective startup can now take place. This is no longer based on the well-known rule of thumb or empirical

Reviews are used, but it is before the actual Magnetization of the asynchronous motor determines a characteristic of this magnetization behavior, so that individual engine interference can be considered in the determination of the optimal magnetizing current. This individual characteristic of the magnetization behavior of the asynchronous machine can also be determined only once and then stored in the memory. For subsequent

Commissioning can then be stored on this in the memory

 Asynchronous individual characteristic can be resorted to when the

Magnetizing current is to be determined for the asynchronous machine.

The core of the present proposed approach is therefore in the

Recording a meaningful motor magnetization (or depending on

 Situation also in the provision of a previously recorded characteristic) and their evaluation. In this way, a high control quality of the asynchronous motor and an optimal power output can be realized because overheating of the

Asynchronous machine can be avoided by Aufnnagnetisierungsverluste.

It is favorable if, in the step of determining the current of the

Magnetizing current is selected from a current intensity interval for the magnetizing current,

wherein for determining the current intensity interval, a first tangent to the characteristic curve is determined, which is an origin straight line through the origin of a

 Coordinate system represents, in which the characteristic is shown,

wherein further in the region of the maximum magnetizing current, a second tangent is determined to the characteristic representing a saturation behavior of the magnetization flux for the maximum magnetizing current, and

further wherein a substantially parallel to the abscissa straight line through the

 Intersection between the first and second tangent is placed and as the upper limit of the current intensity interval, the value of the magnetizing current on the

Abscissa is selected, on which the straight line substantially parallel to the abscissa intersects the characteristic curve. Such an embodiment of the present invention offers the advantage that a magnetizing current, that is, a current to initial

Magnetization of at least one winding (or all windings) of Asynchronmaschine, can be chosen so that the magnetizing current is not in the saturation region of the magnetization current magnetization flux behavior. At the same time, however, by determining the upper limit of

Stromstärkeintervalls the magnetizing current is selected close to the saturation region, so that a fast magnetization of the asynchronous motor is possible. In particular, the magnetizing current may be chosen to assume a value which corresponds to the upper limit of the current intensity interval.

According to another embodiment of the present invention, in the step of determining as the lower limit of the current intensity interval, a value for a

Magnetizing current to be selected on the abscissa of the coordinate system at which intersect the first and second tangent. Such an embodiment of the present invention advantageously ensures that the one selected

Magnetizing current is not too low and thus a fast magnetization of the asynchronous motor is guaranteed.

In order to optimally take into account changes in the mechanical components (for example due to wear after prolonged operation) of the asynchronous motor when determining the current for the initial magnetization, according to a further embodiment of the present invention, the characteristic curve is first determined immediately before the characteristic is used in the providing step become. In this case, the reading out of the characteristic curve from a memory is dispensed with and the characteristic is first determined before the determination of the optimum magnetizing current.

Also, in a further embodiment of the invention in the step of

Providing the characteristic to be determined by a rated current of

 Asynchronous motor is increased from a value of zero to a maximum rated current value for which the asynchronous motor is designed and subsequently reduced back to a value of zero. Such an embodiment of

The present invention ensures that the total magnetization behavior of the asynchronous motor is mapped in its nominal operating range in the characteristic curve. In this way, a very meaningful characteristic can be obtained, which both the Aufnnagnetisierungsverhalten, the Abmagnetisierungsverhalten as well

Images hysteresis effects.

To avoid as far as possible hysteresis effects of partially massive

magnetic elements of the asynchronous motor falsify the recording of the characteristic, should be taken into account for the detection of the characteristic a sufficiently large period of time. In particular, therefore, according to an advantageous

Embodiment of the invention in the step of providing the determination of the

Characteristic curve within a time interval of 10 to 30 seconds, wherein within this time interval an increase and a subsequent reduction of the rated current should take place.

To ensure that for the subsequent operation of the asynchronous motor reliable magnetization 'takes place, should also in a particularly advantageous

Embodiment of the invention in the step of providing the determination of

Characteristic curve at a speed of the asynchronous motor, which is between half of the rated speed and the rated speed.

It is particularly advantageous if the specific magnetizing current is already used immediately after the determination. To this end, according to another embodiment of the invention, the method may further comprise a step of charging the winding of the asynchronous motor with a magnetizing current of the determined current intensity.

The invention will now be described by way of example with reference to the accompanying drawings. Show it:

1 is a block diagram of an asynchronous motor with an associated control device according to an embodiment of the present invention;

 Fig. 2 is a graph showing a characteristic used to determine the optimum magnetizing current for the asynchronous motor according to a

Embodiment of the present invention can be used; and 3 shows a flow chart of a method for determining a strength of a magnetizing current of an asynchronous motor according to an exemplary embodiment of the present invention.

The same or similar elements may be indicated in the figures by the same or similar reference numerals, wherein a repeated description thereof

Elements is omitted. Furthermore, the figures of the drawings, whose

Description as well as the claims numerous features in combination. It is clear to a person skilled in the art that these features are also considered individually or that they can be combined to form further combinations not explicitly described here. Furthermore, the invention is in the following description below

 Use of different dimensions and dimensions explained, the invention is not limited to these dimensions and dimensions to understand. Furthermore, method steps according to the invention can be repeated and executed in a sequence other than that described. If an exemplary embodiment comprises a "and / or" link between a first feature / step and a second feature / step, this can be read so that the exemplary embodiment according to one embodiment includes both the first feature / the first feature and the second feature / the second step and according to another embodiment either only the first feature / step or only the second feature / step.

The present invention now allows, taking into account physical knowledge, to set a magnetizing current of an asynchronous motor. In this case, in particular, a method for determining the magnetization operating point of an asynchronous motor is carried out, this determination taking place by means of a creation of a static magnetization characteristic of the motor as a sensorless control of this asynchronous motor.

The invention thus optimizes the torque generation of the asynchronous motor while reducing its heating by iron losses (for example, magnetization losses). Such a controller is a controller 100 (which is also referred to as a frequency converter in the electrical drive technology) used, which controls an asynchronous motor 120, as shown schematically for example in FIG. 1.

The control unit 100 comprises a memory 130, in which one for the

Asynchronous motor 120 individual characteristic of the magnetization behavior is stored. Such a characteristic can, for example, map the magnetization flux which occurs when a corresponding one or more windings

Magnetizing current flows. This asynchronous motor-individual characteristic in the

Memory 130 can either be determined immediately before use of the characteristic curve or already measured after production of the engine in the laboratory (that is, still at the manufacturer) and then stored in a permanent memory 130.

A measurement of the asynchronous motor-individual characteristic curve can, for example, be such that first a current is conducted through one or more windings of the motor, starting from 0 amps to a maximum current intensity for which the motor is designed. Subsequently, this current through the winding or the windings of the asynchronous motor 120 is again reduced to 0 amps to

Hysteresis effects or a "magnetic inertia" when generating the characteristic curve as possible or to be able to compensate for At the same time should be in the measurement of the asynchronous motor-individual characteristic rising and the

 Dropping the current through the winding or the windings do not take place too quickly, so that the above-mentioned effects are not too strong and thus the characteristic to be recorded is as realistic as possible. For example, the characteristic curve of the asynchronous motor 120 can be measured within a time window of 10 to 30 s, preferably a duration of 20 s, in which the rated current is ramped from 0 amperes to its maximum and again.

The characteristic which is now stored in the memory 130 after the measurement (or permanently as a measurement result of the motor manufacturer for the relevant asynchronous motor 120) is now in the control unit 100 (more precisely in a determination unit 140 of the control unit 100, for example, a processor, computer or to be like that can) to determine the optimum magnetizing current for commissioning the asynchronous motor! 20 used. Such a characteristic may be, for example, the characteristic curve 200 shown in FIG. 2, which is mapped in a coordinate system 210, wherein a magnetizing current in amperes is plotted on the abscissa 220 and a corresponding one on the ordinate 230 of the coordinate system 210

Main field voltage is plotted in volts, which also has a corresponding

 Magnetization flux of the asynchronous motor 120 in Vs (volt-seconds) represents.

In order to arrive at the optimum magnetizing current for the asynchronous motor 120, the characteristic curve 200 is now used according to the representation of FIG. 2, with reference to FIG. 2, the principal evaluation of the characteristic curve in FIG

 Chart (for example, in an oscilloscope function) is explained in more detail. First, a first tangent 240 is in a range of low

Magnetizing currents applied to the characteristic curve 200, wherein the first tangent 240 also represents an original straight line. Furthermore, a second tangent 250 in the range of high magnetization currents is applied to the characteristic 200, so that this second tangent 250 has a saturation behavior of the magnetization at high

Represents magnetizing currents. An abscissa value of an intersection 260 of the first tangent 240 with the second tangent 250 defines a lower limit 270 of a magnetization current to be selected by the controller 100. If now a substantially parallel to the abscissa 220 to the line 280 through the intersection 260, a second intersection point 290 of this straight line 280 is obtained with the characteristic curve 200. An abscissa 295 of this second intersection 290 forms the

Upper limit of a current intensity interval for the selected one

Magnetizing current. It is particularly favorable if the value of the upper limit of the current intensity interval is selected as the magnetizing current. In this case, it can be ensured that as large a current as possible is selected for the magnetization of the asynchronous motor 120, which, however, does not yet result in unnecessary heating occurring in the windings of the asynchronous motor 120. Such undesirable heating would occur especially when in the

Magnetization phase of the asynchronous motor in the windings with a current be applied, which is in the saturation region, as shown in Fig. 2 on the right side of the diagram.

Furthermore, the present invention provides a method for determining a strength of a magnetizing current of an asynchronous motor, as shown in Fig. 3 in the form of a basic flow chart. The method 300 includes a

Step of providing 310 an individual characteristic for the asynchronous motor representing a relationship of a magnetization flux for at least one winding of the asynchronous motor at a predetermined magnetizing current. Furthermore, the method 300 includes a step of determining 320 a magnitude of a magnetizing current for magnetizing the asynchronous motor

Use of the individual characteristic curve for the asynchronous motor.

In summary, it can be noted that during operation of a

Asynchronous machine in the base speed range for optimum power output while avoiding motor heating due to iron loss is an operating point for a magnetizing current "just below saturation." This point is so far set in most electric drive providers using a rule of thumb in relation to the rated current, this rule of thumb only an empirical However, this rule of thumb proves to be inadequate in complying with the hoped-for physical advantages mentioned above.The object of this invention solves this problem metrologically and thus provides a better basis for the efficient commissioning of an asynchronous motor.

LIST OF REFERENCE NUMBERS

100 control unit, frequency converter

 120 asynchronous motor

 130 memory

140 determination unit

200 characteristic

 210 coordinate system

 220 abscissa

230 ordinates

 240 first tangent

 250 second tangent

 260 Intersection of the first and second tangents

 270 abscissa value of the intersection 260

280 substantially parallel to the abscissa straight line

 290 Second intersection between the line 280 and the curve 200

295 abscissa value of the second intersection point 290

300 Methods for determination

310 step of providing

 320 step of determining

Claims

claims

Method (300) for determining a strength of a magnetizing current of an asynchronous motor, said method (300) comprising the following steps:

 Providing (310) an individual characteristic (200) for the

 Asynchronous motor (120), the context of a

 Magnetizing flux for at least one winding of

 Asynchronous motor (120) at a predetermined magnetizing current; and

 Determining (320) a magnitude of a magnetizing current for

 Magnetization of the asynchronous motor (120) using the individual characteristic curve (200) for the asynchronous motor (120).

Method (300) according to claim 1, characterized in that in the step of determining (320) the current strength of the magnetizing current is selected from a current intensity interval (270, 295) for the magnetizing current, a first tangent for determining the current intensity interval (270, 295) (240) is determined to the characteristic curve (200) representing an origin straight line through the origin of a coordinate system (210) in which the

Characteristic curve (200) is shown,

wherein further in the region of the maximum magnetizing current, a second tangent (250) is determined to the characteristic (200), the one

Saturation behavior of the magnetization flux for the maximum

Magnetizing current represents, and

further wherein a straight line (280) substantially parallel to the abscissa (220) is laid through the intersection (260) of the first (240) and second (250) tangents and the upper limit (295) of the current intensity interval (270, 295) Value (270) of the magnetizing current is selected on the abscissa (220) at which the straight line (280), which is essentially parallel to the abscissa (220), is the

Characteristic (200) intersects.

Method (300) according to claim 2, characterized in that in the step of determining (320) as the lower limit (270) of the current intensity interval (270, 295) a value (270) for a magnetizing current on the abscissa (220) of the coordinate system (210 ) at which the first (240) and second (250) tangents intersect.

Method (300) according to one of the preceding claims, characterized in that immediately prior to use of the characteristic (200) in the step of providing (310), the characteristic curve (200) is first determined.

Method (300) according to claim 4, characterized in that in the step of providing (310) the characteristic curve (200). is determined by increasing a rated current of the asynchronous motor (120) from a value of zero to a maximum rated current value for which the asynchronous motor (120) is designed and subsequently reduced again to a value of zero.

Method (300) according to claim 5, characterized in that in the step of providing (310) the determination of the characteristic (200) takes place within a time interval of 10 to 30 seconds, within which

Time interval an increase and a subsequent reduction of the rated current takes place.

Method (300) according to one of claims 5 or 6, characterized

characterized in that, in the step of providing (310), the characteristic (200) is determined at a rotational speed of the asynchronous motor (120) which is between half of the nominal rotational speed and the nominal rotational speed. The method (300) according to one of the preceding claims, characterized in that the method (300) further comprises a step of

 Energizing the winding of the asynchronous motor (120) with a

 Magnetizing the particular current has.

A control device (100) for determining a strength of a magnetizing current of an asynchronous motor (120), wherein the control device (10 O) has the following features:

 a storage unit (130) configured to provide an asynchronous motor individual characteristic (200), the characteristic (200) representing a relationship of the magnetization flux for a winding of the asynchronous motor (120) at a predetermined magnetizing current; and

 a determination unit (140) configured to determine a current intensity of a magnetizing current of the asynchronous motor (120) using the asynchronous motor-individual characteristic (200).

Computer program with program code for carrying out the steps of the method (300) according to one of claims 1 to 9, when the

 Computer program on a control unit (100) is executed.