DE3939304A1 - Rotating field testing method for three phase motors - using test head consisting of three concentrically wound coils mounted on core assembly - Google Patents

Abstract

The correct inter-connection of stator windings in a three phase motor can be determined by evaluating the amplitude and phase of electro-magnetic induction produced in a test head by the stator systems rotating field. The test head (200) consists of three concentrically wound coils (201.202.203) mounted on a cone assembly (205) which allows correct penetration into various sizes of stator system (1.2.3) and up to 5 degrees of tilt for optimum magnetic coupling. The test head (200) has a universal application regarding number of stator pole pairs and its output can be connected to automatic test equipment for evaluation purposes. USE/ADVANTAGE - Quick and accurate method of locating stator winding problems. Universal test head can be connected to automatic test equipment for results evaluation.

Description

The invention relates to a method for testing the Rotating field in stator systems, especially in stator winding lungs of three-phase motors, by detecting the electro magnetic induction of the stator system Coil arrangements. The invention also relates on the associated device for performing the method with a measuring head carrying measuring coils.

Wiring errors in the stator affected by three-phase motors their behavior in terms of efficiency, torque and Smooth running sustainable. Such errors must therefore before Soak the windings or assemble a motor known and repaired if necessary. Regarding ver Wiring faults in three-phase motors are common in practice the following cases are particularly relevant:

• - Swapping two phases, causing a wrong sense of rotation is caused
• - The beginning and end of a partial winding of a phase are ver swaps
• - one phase is missing,
• - The beginning and end of a phase are confused.

So far, manufacturing has been a simple, but little differentiated statement about the rotating field of a stator Current supply to the three winding phases with three-phase current and observ eight one rotatably inserted into the interior of the stator stored cage rotor or magnet achieved. So that can  but generally only three possible state statements be directed, namely a left-turning, a right-turning or no rotating field. By traversing the inner circumference of the Experienced test personnel also allow stator irregularities Detect the regularity of the rotating field. Such an approach wise is time-consuming and cannot be automated.

It is also a test head equipped with Hall sensors known (thesis Th. Hauser - FHS Nürnberg 29.04.1988), which detects the magnetic field occurring in the stator interior and Deviations from a desired field geometry can be recognized. There is a specific for each stator size and slot pitch shear test head required. Because with a Hall sensor because of that small cross-sectional area always only a small proportion of the flux Stator magnetic field can be detected and never the total flux of a pole or the coil system of a phase is the Limited application possibilities. Also needs a reverb sensor a control current, which makes complex sensor systems Potential problems can arise.

The object of the invention is therefore to provide a test method create that works with coil assemblies, and the zuge specify hearing device. The essential point is that the process can be automated and given if it can be integrated into a complex test station.

The object is achieved in that with little least one coil arrangement measured from two individual coils is that the induction voltages of the individual coils after Amplitude and phase are evaluated and that a Signal for the correct switching of the winding or for one Switching error is derived. The number corresponds to Coil arrangements of the number of pole pairs of the stator system.  

Cross-wound coils or segment can be used as coil arrangements coils are used. The latter in particular can be Arrange on a measuring head to save space.

In the associated device for performing the Ver driving are to use the same measuring head at un different stator systems as test objects for one under different number of pole pairs designed coil arrangements arranged on the measuring head. Preferably, the Spu Len arrangements arranged in a disc shape one above the other. Provided segment coils can be used as coil arrangements designed for a different number of pole pairs Coil arrangements also concentric around a central axis be arranged.

The invention thus creates a universal head that is suitable for a wide variety of applications. Here either the measuring head can have a support ring for the stator system that depends on the diameter of the test object. So that the coil arrangement is one of the speci brought the height of the test specimen. Alternatively the measuring head can also have a cone for the test object form so that depending on the inner diameter ent speaking position is taken.

In the context of the invention is advantageously the measuring head evaluation electronics for evaluating the measured induct tion voltages and display of the measurement result assigned. The evaluation electronics can be a microcontroller or one Personal computer (PC).

Further details and advantages of the invention emerge from the following figure description of execution play with the drawing in connection with other sub claims. It shows  

Fig. 1 a stator having a pair of poles including field trials distribution and cross-wound bobbin as a measuring sensor,

Fig. 2 shows the amounts of the set with the cross-wound bobbin of FIG. 1 taken induced voltages in XY display,

Fig. 3 is an electrical equivalent circuit diagram of a stator system,

Fig. 4 shows a stator with two pole pairs and meßgerechter arrangement of two cross-wound bobbins,

Fig. 5 shows a stator with two pole pairs, and with meßgerechter arrangement of two segmental coils,

Fig. 6 shows a stator with three pole pairs and meßgerechter arrangement of three cross-wound bobbins,

Fig. 7 is a three-pole stator with three pole pairs and with meßgerechter arrangement of three segmental coils,

Fig. 8 shows a first embodiment of a universal measuring head and

Fig. 9 shows a second embodiment of a universal measuring head.

In Fig. 1, a stator 1 of a three-phase asynchronous motor consists essentially of three coils U, V and W, which are arranged on the circumference of the stator 1 and the poles U +, W-, V +, U-, W + and V clockwise - form. It can be shown that a homogeneous field with a flux Φ forms within the stator 1 , which rotates clockwise at the speed ω.

In the field with flux Φ there is a coil arrangement 10 made up of disc-shaped individual coils 11 and 12 standing perpendicular to one another, which together form a cheese. When the field in the stator 1 rotates, the flux change in the fixed individual coils 11 and 12 corresponds to position X and Y in induction voltages, which are denoted by U _x and U _y . It can be shown that the induction voltages U _x and U _{y have} the same amplitude and a phase shift of 90 ° and -90 °. If the voltages U _x and U _{y are applied in} phase in an XY representation according to FIG. 2, the circuit results in a circular profile of the voltage signal if the circuit is correct.

Such a signal can be displayed on an oscilloscope will. The direction of rotation of the rotating field is determined by the movement of the illuminated dot is reproduced on the screen. Any deviation from the circular course indicates one Error in the stator system. An error analysis can now more immediately on the faulty phase in the stator wick be closed.

In Fig. 3, the three strands U, V and W are excited with the three phases L 1 , L 2 and L 3 of a symmetrical three-phase system. Each strand consists of two sub-coils, with the windings U 1 and U 2 , V 1 and V 2 and W 1 and W 2 . The beginnings (A) and the ends (E) of the partial coils are also shown. Stators with three, four or more coil sections per strand can be designed accordingly.

If the stator has two pole pairs or more, the field becomes strong inhomogeneous. It gets around from the center of the stator bore the more the higher the number of pole pairs is displaced. It goes the rotating field into a traveling field, which is on the inner Circumference of the stator runs along. An exact math A description of such a field is not easily possible Lich. In any case, the magnetic field is spatially periodic regarding a sector with the angle

ϕ mech = 360 ° / p,

where p represents the number of pole pairs. 360 ° electrical ent speak a mechanical angle of 360 ° / p. At a four-pole stator this corresponds to 180 °, six-pole arrangement conditions repeat after 120 ° and eight-pole after 90 °. The ge Entire magnetic field system moves within an electrical Period by exactly this angle in the direction of rotation without to change its overall shape.

In FIG. 4 and FIG. 5, a stator 2 is shown in each case with two pairs of poles and inner diameter d. On the circumference of the stator 2 are the poles U 1 +, W 1 -, V 1 +, U 1 -, W 1 +, V 1 -, U 2 +, W 2 -, V 2 +, U 2 - in a clockwise direction. , W 2 + and V 2 - indicated. The symmetry of the half fields along the dashed line can be seen. Due to the symmetry in this case, two coil arrangements have to be measured.

In FIG. 4, a first coil assembly 20 is shown from two mutually perpendicular coils 21 and 22 in the right sector, and a second coil assembly 30 of two mutually perpendicular coils 31 and 32 in the left sector. As an alternative to this, two coil arrangements 120 and 130 can be used in FIG. 5, each comprising two segment coils 121 , 122 and 131 , 132 offset from one another. The alternative choice of cross-wound bobbins or segment bobbins is electrotechnically equivalent. The spatial configuration of a cross-coil arrangement with the associated induction voltages is clear from FIG. 1 and the associated XY representation according to FIG. 2. In the case of a segment coil arrangement, the individual coils form a saddle shape with the same induction behavior. The segment coils lie on a circle with a diameter d _s concentric in the stator 2 .

In order to be able to control the smooth movement of an electric rotating or traveling field, two sensor coils are always necessary, which are electrically offset from each other by 90 °. This can be seen immediately in the cross-coil arrangement 10 according to FIG. 1 if it is used for a stator with a pair of poles. In this 90 ° electrical are also 90 ° mechanical at the same time, so that the two perpendicular disc-shaped coils 11 and 12 as a cross coil meet the above-mentioned condition.

However, the situation is different with multi-pole stators. 360 ° electrical there correspond to a mechanical angle of now 360 ° / p. B. 120 ° mechanically with three pole pairs. Specifically, the individual segment coils 121 , 122, and 131 and 132 of the coil arrangements 120 and 130 according to FIG. 5 are each mechanically offset by 90 ° / p. Each coil section 121 , 122 , 131 , 132 therefore covers a segment of 180 ° / p.

The latter arrangements of segment coils behave like that corresponding multiple cross-wound bobbins. Because especially at high pole systems of mechanical construction of packages is equally complicated in this case is due to the compact design such a segment coil arrangement a grooved cylindrical plastic carrier partial.

To further clarify 7 stators each having three pairs of poles in the windings is shown in Figs. 6 and FIG. Asked. The order of the poles U 1 +, W 1 -, V 1 +, U 1 -, W 1 +, V 1 -, U 2 +, W 2 -, V 2 +, U 2 - results here again clockwise. , W 2 +, V 2 -, U 3 +, W 3 -, V 3 +, U 3 -, W 3 + and V 3 -. The symmetry of the segments is 120 °. Accordingly, in Fig. 6 three cheese packages 20 , 30 and 40 with a single coils 21 , 22 , 31 , 32 , 41 and 42 are available. The segment coil arrangements 120 , 130 and 140 with segment coils 121 , 122 , 131 , 132 , 141 and 142 offset from one another are quite correspondingly present in FIG. 7. The individual segment coils 121 and 122 or 131 and 132 or 141 and 142 are each offset by 30 ° and each comprise an angle of 60 °.

In the arrangements according to FIGS. 4 and 5 or 6 and 7, there should be a spatial relationship between the respective coil system and the stator for a phase-specific error statement. Regardless of the spatial reference, it is always recognized whether the rotating or traveling field is correct or disturbed.

In all cases, the diameter d _{s of} the coil arrangements only affects the size of the voltage that can be evaluated, not the error detection itself. For example, the ratio of the inner stator diameter d _i to the coil diameter d _s of two to three has been found to be the optimal value. To a certain extent, the coil arrangements can be eccentric to the stator without the error detection being significantly influenced. An angle of inclination between the coil system axis and the stator axis is also possible.

In Fig. 8, a measuring head is shown, which consists of a platform 100 with a central support 110 . The latter carries on its upper part, coil assemblies 101 through 103, which, as sensors for stator systems with different numbers of pole pairs corresponding to FIG. 1 one hand and Fig. 4, 5 and FIG. 6, 7 on the other hand are used are formed.

In FIG. 8, the coil assemblies are specifically designed for sensor systems with numbers of pole pairs p = 1, p = 2 and p = 3 superposed. In order that the coil arrangements are each immersed in a defined depth of the stators 1 , 2 or 3 , a support ring 105 is further arranged on the platform 100 , the dimensions of which are dependent on the test object. The support ring 105 is approximately horseshoe-shaped in plan view and has a lateral recess 106 for the leads of the stators. It is made of non-ferromagnetic material to avoid field distortions.

As an alternative to this, a measuring head 200 is shown in FIG. 9, which forms a receiving cone 210 for test specimens of different designs in the upper part. The receiving angle of the receiving cone 210 is dimensioned such that the coil arrangements are always within the winding of the stator system. A certain tilt with an inclination angle of up to about 5 ° is therefore possible. In this case, three coil arrangements 201 to 203 as sensors are arranged concentrically.

In particular, the device according to FIG. 9 thus represents a universal test head with which measurements can be carried out in the usual stator systems in practice, regardless of the type of coil arrangement selected. It can be used for the different number of pole pairs, the thickness of the laminated core to be expected and the usual diameters, so that it does not have to be changed over a wider range of types. The sensor coil system is dimensioned for the smallest inside diameter. It can be connected directly to evaluation electronics.

In principle, the measuring heads according to FIG. 8 and FIG. 9 can be provided as separate test devices each with their own evaluation electronics or as part of a comprehensive automatic test machine. In the first case, a microcontroller is present as evaluation electronics; on the other hand, use is made of a personal computer in the second case, with which a statistical evaluation of the results and graphic display on a screen is also possible.

The method according to the invention and the associated device was especially used to test stator windings for turning current motors described in which due to the symmetry the rotating fields or hiking fields in the normal case a circular signal is expected and each Deviation indicates a significant error. But also for other applications of stator systems, e.g. B. with Single phase alternating current and capacitor auxiliary phase are working the invention applicable. In this case, ver  wired stator system already a deviation of the signal from the circular shape are present as a master curve in a computer is stored. Deviations from this saved standard curves are recognized as errors.

Claims (23)

1. A method for testing the rotating field in stator systems, in particular in stator windings of three-phase motors, by detecting the electromagnetic induction of coil arrangements introduced into the stator system, characterized in that with at least one coil arrangement from two individual coils is measured that the induction voltages of the individual coils are evaluated according to amplitude and phase and that a signal for the correct switching of the winding or for a switching error is derived therefrom. 2. The method according to claim 1, characterized records that the number of coil arrangements of Corresponds to the number of pole pairs of the stator system. 3. The method according to claim 2, characterized records that for a stator with a pole pair Coil arrangement is used. 4. The method according to claim 2, characterized records that for a stator with two pole pairs two coil arrangements, which are mechanically against each other by 180 ° are arranged offset. 5. The method according to claim 2, characterized records that for a stator with three pole pairs three coil arrangements, which are mechanically against each other by 120 ° are arranged offset. 6. The method according to claim 2, characterized records that for stator systems with n pole pairs n Spu lenan arrangements that are mechanically offset from each other by 360 ° / n are used.   7. The method according to claim 1, characterized records that cross coils are used as the coil arrangement be det. 8. The method according to claim 7, characterized records that the individual coils of the cross coils lower stand right on each other. 9. The method according to claim 1, characterized records that ver as a coil arrangement segment coils be applied. 10. The method according to claim 8, characterized records that the individual coils of the segment coils each are arranged by 90 ° / p, where p is the number of pole pairs in Is stator system. 11. The method according to claim 9 and 10, characterized ge indicates that of each segment coil in the stator system a segment of 180 ° / p is covered. 12. An apparatus for performing the method according to claim 1 or one of claims 2 to 11, with a measuring coils carry the measuring head, characterized in that for using the same measuring head ( 100 , 200 ) with different stator systems ( 1 , 2 , 3 ) as test objects with the designed for a different number of pole pairs coil arrangements ( 101-103 , 201-203 ) are arranged on the measuring head ( 100 , 200 ). 13. The apparatus according to claim 12, characterized ge indicates that the coil assemblies are disc are arranged in a shape one above the other.   14. The apparatus according to claim 13, characterized in that the height of the stacked coil arrangements ( 101-103 , 201-203 ) is in the same order of magnitude as the smallest package thickness of the test specimens. 15. The apparatus of claim 12, wherein the coil assemblies consist of segment coils, characterized records that the segment coils are arranged concentrically are. 16. The apparatus according to claim 12, characterized in that the measuring head ( 100 ) has a support ring ( 105 ) for the stator system ( 1 , 2 , 3 ), which is dependent on the test specimen diameter. 17. The apparatus according to claim 16, characterized ge indicates that the support ring is not made terromagnetic material exists. 18. The apparatus according to claim 16, characterized in that the support ring ( 105 ) is hoof iron-shaped with a recess ( 106 ) for the feed lines. 19. The apparatus according to claim 12, characterized in that the measuring head ( 200 ) forms a receiving cone ( 210 ) for the test object. 20. The apparatus according to claim 19, characterized in that the angle of inclination of the receiving cone ( 210 ) is dimensioned such that the coil arrangements ( 201-203 ) are located within the winding of the stator system. 21. The apparatus according to claim 12, characterized in that the measuring head ( 100 , 200 ) is associated with evaluation electronics for evaluating the measured induction voltages and display of the measurement result. 22. The apparatus according to claim 21, characterized ge indicates that the evaluation electronics Is microcontroller. 23. The device according to claim 21, characterized ge indicates that the evaluation electronics Personal computer (PC) is a complete mistake analysis is delivered.