DE19707860A1 - Contactless monitoring arrangement for rotary machine part - Google Patents

Abstract

The arrangement includes a transformer whose primary part is stationary and whose ferromagnetic parts include circular inner contours. A secondary part is arranged on the rotary machine part and is separated by an air gap. The secondary part has circular outer contours and a sensor or switch which is connected to the secondary windings using electrical wires. The secondary part changes the impedance of the sensor or the switch in dependence of physical values. The primary ferromagnetic part has only one gap partly or completely passed through from the inner edge to the outer edge. The secondary ferromagnetic part may have only one gap partly or completely passed through from the inner edge to the outer edge. The primary ferromagnetic part and the secondary ferromagnetic part may have only one gap partly or completely passed through from the inner edge to the outer edge.

Description

The invention relates to an arrangement for the contactless monitoring of physical quantities of a rotating machine part. The rotating Machine part can e.g. B. the rotor of an asynchronous machine or one Be synchronous machine. The size to be monitored can e.g. B. the temperature of the Rotor rod of the asynchronous machine or the field winding of the Be synchronous machine.

Such an arrangement is e.g. B. from DE-OS 25 09 002 or DE-PS 33 13 418 C2 known. The arrangements described therein exist u. a. from a transformer or transformer with a fixed primary part and a rotating one Secondary part.

The arrangement is characterized in that the frequency of the voltages and Currents in the secondary part independent of the frequency of the primary Corresponds to voltages and currents.

To the secondary winding z. B. thermal switch or PTC thermistor connected will. At a certain temperature, the impedance of the sensor changes. For example, the thermal switch opens a contact or the PTC thermistor increases its ohmic resistance almost suddenly. This naturally changes also the impedance of the entire secondary circuit. This change in impedance can you can also see on the primary side. Is z. B. the primary side to one AC voltage source connected, so flows when the contact is closed (small impedance) a large primary current. If the contact opens (high impedance), then a smaller current flows on the primary side.

The difference in the primary current can be easily evaluated by measurement. The The temperature of the rotor can be easily, safely and without contact monitor. The runner can e.g. B. by switching off the machine before too large Warming and be protected from damage.

Figure 1 shows a possible structure in the view, Figure 2 shows the structure in section.

The transformer consists of the primary iron core ( 1 ), the secondary iron core ( 2 ), the primary winding ( 3 ), the secondary winding ( 4 ) and a hub ( 6 ) for receiving the rotor shaft of the machine to be monitored. There is an air gap ( 5 ) between the primary and the secondary iron core.

For the operation of this arrangement, it is important that the impedance Difference of the secondary side to the greatest possible difference of the Leads primary current, d. H. that the transmitter has the highest possible sensitivity owns. This can be done by a small air gap between the primary and Secondary side, due to low saturation, small scattering reactions and Winding resistances and by largely avoiding eddy currents to reach.

The effect of the eddy currents can be simulated in the replacement image of the transformer ( Figure 3) by the current I _Fe , which flows through the resistor R _Fe . It can be seen that with large eddy currents (large current I _Fe ), a large primary current I ₁ flows even when the transformer is idling (I ₂ = 0). With additional secondary current I ₂ , the primary current increases from a higher level. The sensitivity is less than with small eddy currents. Another disadvantage of eddy currents is the heat development associated with them.

In DE-OS 25 09 002 a structure of the laminated cores with individual U- or L-shaped sheets shown, the sheets are layered into rings. The Sheets are layered in the tangential direction of the sheets. This arrangement is fulfilled in principle the demand for the prevention of eddy currents. The disadvantage is however, the high manufacturing effort required for this and the associated associated high costs.

The object of the present invention is to monitor the runner simply constructed, easy to manufacture and therefore inexpensive transformer to describe the above all the formation of eddy currents in a simple way avoids.

Knowing the eddy current paths (current density lines) is important to avoid eddy currents. To determine them, one can be guided by the idea that the eddy currents are similar to the currents that generate them (see also: Induction Law, Lenz's Rule). In Figure 4, the top view of the transformer also shows some eddy current paths ( 9 ) in the primary iron core and some eddy current paths ( 10 ) in the secondary iron core. Figure 5 shows the transformer in section and the corresponding eddy current paths. Since the primary current ( 7 ) in the primary winding ( 3 ) and the secondary current ( 8 ) in the secondary winding ( 4 ) flow in the tangential direction, tangentially directed eddy currents also arise in the iron parts. To prevent the eddy currents, a single interruption of the eddy current paths is sufficient.

The avoidance of eddy currents to increase the sensitivity of the transmitter is achieved according to the invention in that the primary or the secondary iron part or both iron parts have only a single gap that extends completely or partially from the inner edge to the outer edge. Figure 6 shows the top view of the transmitter with a primary gap ( 11 ) and a secondary gap ( 12 ).

Embodiment

Figure 7 shows an embodiment of the invention in a top view. Figure 8 shows the sectional view. The temperature monitoring of the rotor cage of an asynchronous machine is considered.

The primary iron core ( 1 ) is made of circular sheets. Two different sheet metal cuts (with the same outside diameter but with different inside diameters) were used. The laminated core can be held together by welding seams, rivets or screws. The laminated core has three holes ( 16 ) which are used to hold screws for fastening the primary part to the grease chamber cover.

The secondary iron core ( 2 ), which was also made with two sheet cuts, is mounted on a sleeve ( 6 ) that can accommodate the shaft of the machine to be monitored. The secondary iron core ( 2 ) can, for. B. be secured by welds ( 17 ) on the sleeve ( 6 ).

Primary and secondary windings are wound on coil carriers ( 18 ) and ( 19 ) which are open to the outside. The winding ends ( 20 , 21 ) are led out of the iron cores through the radial gaps ( 11 , 12 ) of the laminated cores.

Figure 9 shows a basic diagram of rotor monitoring.

The secondary winding ( 4 ) is connected via electrical lines ( 13 ) along the shaft ( 15 ) of the machine to be monitored with a thermal switch ( 14 ), which is removed from the transmitter, for. B. is attached to the short-circuit ring of the asynchronous machine. The contact of the thermal switch is closed at low temperature. The contact opens at the set higher temperature.

The primary winding ( 3 ) is connected directly to the normal 50 Hz AC network ( 22 ) via electrical lines. The level of the primary current is measured with a simple electronic circuit ( 23 ). If the primary current falls below a certain threshold value, the electronics ( 23 ) trigger an alarm or switch off the asynchronous machine from the mains.

Claims (28)

1. Arrangement for the contactless monitoring of physical quantities of a rotating machine part, consisting of a transmitter, the primary part of which is fixed in a stationary manner and the ferromagnetic parts of which have circular inner contours, and a secondary part which is separated by an air gap and fastened on the rotating machine part and whose ferromagnetic parts have circular outer contours and with at least one sensor or switch connected via electrical lines to the secondary winding, which causes a change in the impedance of the sensor or switch depending on the physical variable, characterized in that the primary ferromagnetic part is only a single one from the inner edge to the outer edge or has a partially continuous gap or the secondary ferromagnetic part has only a single fully or partially continuous gap, or the primary ferroma The magnetic part and the secondary ferromagnetic part each have only a single gap that runs completely or partially from the inner edge to the outer edge. 2. Arrangement according to claim 1, characterized in that the ferromagnetic primary part of the transmitter from individual, in the axial direction to form a laminated core laminated sheets with a circular inner contour. 3. Arrangement according to claim 1, characterized in that the ferromagnetic secondary part of the transmitter from individual, in axial Towards a laminated core, laminated sheets with a circular outer contour consists. 4. Arrangement according to claim 1, characterized in that the ferromagnetic primary part of the transmitter with a solid part circular inner contours. 5. Arrangement according to claim 1, characterized in that the ferromagnetic secondary part of the transformer with a solid part circular outer contours. 6. Arrangement according to claim 1, characterized in that the ferromagnetic primary part of the transmitter from massive, in the axial direction layered parts with circular inner contours. 7. Arrangement according to claim 1, characterized in that the ferromagnetic secondary part of the transformer made of solid, in axial In the direction of layered parts with circular outer contours. 8. Arrangement according to claim 1, characterized in that the ferromagnetic primary part of the transmitter from massive, in the radial direction layered parts with circular inner contours. 9. Arrangement according to claim 1, characterized in that the ferromagnetic secondary part of the transformer made of massive, in radial In the direction of layered parts with circular outer contours. 10. The arrangement according to claim 1, characterized in that  the ferromagnetic primary part of the transformer made of solid, in axial and in parts in the radial direction with circular inner contours. 11. The arrangement according to claim 1, characterized in that the ferromagnetic secondary part of the transformer made of solid, in axial and there are parts layered in the radial direction with circular outer contours. 12. Arrangement according to one of the preceding claims, characterized characterized in that the primary ferromagnetic parts or the secondary ferromagnetic parts or both are connected with additional metal parts. 13. Arrangement according to one of the preceding claims, characterized characterized in that the sensors are thermal switches. 14. Arrangement according to one of the preceding claims, characterized characterized in that the sensors are pressure switches. 15. Arrangement according to one of the preceding claims, characterized characterized in that the sensors are PTC thermistors. 16. Arrangement according to one of the preceding claims, characterized characterized in that the sensors are thermistors. 17. Arrangement according to one of the preceding claims, characterized characterized in that the sensors are resistance conductors. 18. Arrangement according to one of the preceding claims, characterized characterized in that several sensors are connected in parallel.   19. Arrangement according to one of the preceding claims, characterized characterized in that several sensors are connected in series. 20. Arrangement according to one of the preceding claims, characterized characterized in that the change in impedance of the secondary side is carried out by measuring the primary current. 21. Arrangement according to one of the preceding claims, characterized characterized in that the change in impedance of the secondary side by measuring the primary voltage he follows. 22. Arrangement according to one of the preceding claims, characterized characterized in that an electrical energy source is connected to the primary side. 23. Arrangement according to one of the preceding claims, characterized characterized in that as an energy source the normal AC network with a frequency of 50 Hz or 60 Hz is used. 24. Arrangement according to one of the preceding claims, characterized characterized in that the primary side of the transmitter on the end shield of the machine to be monitored is attached. 25. Arrangement according to one of the preceding claims, characterized characterized in that the primary side of the transmitter on the grease chamber cover of the one to be monitored Machine is attached. 26. Arrangement according to one of the preceding claims, characterized characterized in that  the primary side of the transformer on the stator housing of the to be monitored Machine is attached. 27. Arrangement according to one of the preceding claims, characterized characterized in that the primary side of the transformer electrically with a trigger device and the Energy supply is connected. 28. Arrangement according to one of the preceding claims, characterized characterized in that the transformer is short-circuit proof.