DE819288C - Testing device for armature of DC machines - Google Patents

Description

Testing device for armatures of DC machines To the anchors of To test direct current machines for interturn shortfalls, it is known to use an alternating field to act on the anchor, which induces a voltage in the anchor windings, which can be measured on the collector fins. This induced voltage is proportional to the frequency and the power flow of the alternating field.

Therefore, if a high frequency is used, a relatively smaller one Sufficient force flow to generate test voltages of sufficient magnitude in the anchor windings to induce; the iron cross-sections of the test yoke can then be correspondingly small be dimensioned so that the test equipment is manageable; however, is for generation The alternating current of high frequency requires a special period converter.

If such a small test yoke is operated with mains frequency, then amount to the induced test voltages in the windings are only fractions of those during operation occurring values. It can indeed be used to determine interturn shortfalls or interruptions but not those faults where voltage breakdowns as a result of defective insulation occur between the winding insulation.

These only maintain between a certain voltage potential the windings concerned to appear. To have sufficient test voltages must be achieved by the anchor to be tested when using the mains frequency Skilful magnetic flux have approximately the normal number of lines of force and the test yoke accordingly have large iron cross-sections. It is essential that the Armature rests tightly on the test yoke with as little air gap as possible, as it is present many ampere-turns of an air gap, i.e. a considerable reactive kVA power must be expended to drive the magnetic flux through the air gap.

In the known test devices of this type, in each case only place anchors of a certain diameter in a well-fitting manner; so you need a special device or at least special support poles for each anchor model.

The invention relates to a test device, Which using the method described, testing of any anchors Size within a certain range with sufficiently high test voltages allows. This is achieved by the invention in that the support poles are arranged to be adjustable and curved according to a mean anchor diameter of the application area are. The support poles are preferably arranged displaceably along a yoke piece, and aids can be provided which ensure a parallel shift, so that the contact surface of the poles is set up in each case parallel to the armature axis is. The position assigned to the individual anchor diameters can be determined by means of a scale be marked. A clamping device is expediently provided which Clamp the support poles tightly to the yoke to avoid humming in the company.

An embodiment of the invention is shown in the drawings. It shows Fig. 1 schematically the basic arrangement of the test device, Fig. 2 shows a support pole and the yoke in a view, FIGS. 3 and 4 show the arrangement schematically when testing anchors of different diameters.

Poles 2 and 3 sit on a yoke I, the free end of which is for receiving an armature to be tested 4 is curved. The yoke I carries a winding 5, which can be connected to the 220 V or 380 V alternating current network by means of a switch 6 can. An indicator 7 enables the excitation current to be measured. The one when excited Magnetic flux 8 induced in the yoke passes through the windings g of the armature 4 and induces the test voltage in them. This induces in the outside of the magnetic flux 8 arranged measuring circuit 10 currents which can be read on the indicator II '.

The yoke I and the support poles 3 (Fig. 2) are layered from sheet metal. Each pole 3 sits flat on the upper surface of the yoke I and can along this be moved. The side plates 12 of the pole 3 carry lugs I3, which Yoke I grip around and on which an axis 14 is mounted. The axis can by means of a handle 15 to be rotated; it carries eccentric I6, which against the lower one Act on the surface of the yoke 1 and pull the pole 3 downwards so that it is fixed is pressed onto the yoke.

The yoke carries a scale I7, under which the extension 13 passes, which is expediently provided with a marking I8. The scale indicates the position of the pole 3 assigned to the individual armature diameters.

To move the pole 3 is on the yoke I in the plates 19 an axle 20 is mounted which can be rotated by means of a handle 21. The axis carries near their bearings two levers 22 which engage two levers 23 which are connected to the plates 12 of the pole 3. By pivoting the handle 21 can thus the pole 3 on the upper surface of the yoke I can be moved.

By means of a coupling (not shown) that is associated with the two poles 2, 3 Axes 20 on both sides of the yoke can be handled by means of a single handle the poles 2, 3 are moved together. Those attacking the outside of each pole Lever 23 make sure that the poles are shifted exactly parallel to theirs Support surfaces thus always run parallel to the anchor axis.

The contact surface 24 of the pole is middle corresponding to an anchor Curved in diameter.

If an anchor 4 of smaller diameter is placed (Fig. 3), then the poles 2, 3 moved closer to each other. Against the edges of the support surface 24 exists then a small air gap 25 between armature and pole face.

To test an armature 4 with a large diameter, the poles 2, 3 pushed further apart (Fig. 4). Such an anchor lies on the edges of the pole face 24, in the middle of which a small air gap 26 remains to the armature. The curvature of the pole face allows for a mean different diameter it in connection with the displaceability of the poles that the loss through air gaps remains low; the same test facility is therefore different for testing anchors Size suitable by means of voltages induced in the windings.

PATENT CLAIMS: I. Testing device for armatures of DC machines, in which voltages at least at operating level are induced by means of an alternating field are, characterized in that to achieve sufficiently high test voltages The support poles (2, 3) are arranged to be adjustable in anchors of various diameters and are curved according to an average diameter.

Claims (1)

2. Testing device according to claim I, characterized in that the Support poles (2, 3) are arranged so that they can be locked along a yoke (1). 3. Testing device according to claim I and 2, characterized by a Scale (I7) showing the position of the support poles (23) depending on the armature diameter indicates. 4. Testing device according to claim I and 2, characterized by a Clamping device (14 to I6), which firmly connects each support pole with the yoke made possible. 5. Test device according to claim I and 2, characterized in that that an adjusting device (20 to 22) mounted on the yoke (I) on both sides of each pole (3) attacks. 6. Test device according to claim I, 2 and 5, characterized that both poles are moved together on the yoke by means of the same handle.