DE865534C - Shock knife - Google Patents

Description

Vibration meter The invention relates to vibration meters, especially for determining the unbalance size in-balancing machines is based on the principle of electromagnetic induction. The mechanical vibrations are converted into electrical alternating voltages in these vibration meters. This is achieved by placing coils in strong magnetic fields which move through the mechanical vibrations. The introduction this movement happens either directly from the vibrating object via a with the probe tip connected to the coil system, while the housing of the vibration meter is established, indirectly in such a way that the housing of the vibration meter to is attached to the object to be tested and due to the inertia of the vibrating System relative movements of the voice coils with respect to the housing arise.

The dissipation of these induced voltages in the usual way via connecting wires or flags from the vibrating system to the fixed points impairs the free vibration. This means that if the vibration meter is used, the calibration capability is in question and, on the other hand, that at these points, when high acceleration forces occur, breaks often occur at junctions. In the case of balancing machines in particular, the vibration meters are subject to very different loads . H. with large imbalances, large amplitudes arise. On the other hand, the fine balancing is also carried out with the same devices. Now join large amplitude deformations at the waste leitu'äg # .verbinduliken the contact transitions, so the evaluation of- calibration curves is illusory, and the fine balancing is questioned.

The invention described below eliminates these deficiencies and guarantees a high level of operational safety and accuracy and the unconditional Guarantee for the reproducibility of the test persons.

The details of the invention are shown in the drawing, for example. In Fig. I, a vibration meter is shown in axial section; Fig.:2 contains the vibration meter in a modified form; Fig. 3 shows the circuit of the entire measuring device.

According to the fig; i, the housing of the vibration meter contains two moving voice coils i and 2 fixed to the housing in the field. The voice coils are attached to a rod 4 which is suspended from metallic membranes 6 and 8 in the housing. The membranes are electrically isolated both from the rod 4 and from the housing. Two fixed contacts 7 and g, which are made as rings of conductive material and are electrically connected to the eyebrows, are used to connect the display instrument for the voltages induced in the voice coils i and 2.

As can be clearly seen from Fig. 3 , the coils i and: 2 are connected in series via their wire connections 3 and 5 and the rod 4. The beginning of the voice coil i is attached to the vibrating part of the metallic membrane 6 and is conductively connected via this to the contact 7 fixed to the housing; the end of the voice coil 2 is in a conductive connection via the metallic membrane 8 with the contact 9 fixed to the housing. The derivation of the voltage is therefore carried out without any additional electrical connection or lines or elastic spirals, solely via the mechanical connections of the components of the vibration meter that are already present.

Fig. 2 shows in axial section a vibration meter in which parts i to 9 have the same meaning as in the device shown in Fig. I. The bumper 4 is provided here with an axial bore in which the connecting lines to the individual coils are embedded.

Vibration meters can also be designed according to this arrangement with more voice coils than those described here. The electrical connection from voice coil to voice coil is via mechanical aids, e.g. B. rods, which sit isolated in the coils, made. The voltage is diverted in the first and last voice coil via the membrane eyelets to the contacts 7 and 9 fixed to the housing in a manner analogous to that in the previously described embodiment.

The vibration meter can also be equipped with a voice coil for the for the purposes described. In this embodiment there is one Derivation of the induced voltage once across the membrane, which insulates immediately sits near the voice coil, to one contact fixed to the housing and the second Dissipation via the bumper and the second membrane, on which the voice coil is attached to the other housing-fixed contact for the display device.

The magnet fixed to the housing can be either a permanent magnet or an electromagnet be.

The membranes can be spoke, spiral or lattice membranes as well as in all possible variations, as z. B. for centering the voice coils used in loudspeakers.

The vibration meter is attached to the measuring tip with its scanning tip z. B. placed rotating body, causing the voice coils to vibrate -will.

Claims (3)

PATENT CLAIMS-. i. Vibration meters, in particular for determining the unbalance size in balancing machines, or vibration meters generally with one or more voice coils influenced by magnetic fields, characterized in that the voice coils are connected to membranes (6, 8) or similar aids which are used for the vibratory mounting of the vibrating system, with contacts (7, 9) fixed to the housing, to which the display device for the voltage induced in the coils is connected. : 2. Vibration meter according to claim i when using several voice coils, characterized in that the electrical connections from voice coil to voice coil via mechanical parts of the vibratory system, e.g. B. a for parallel guidance of the coils serving rod (4) take place and that the first and the last voice coil is in conductive connection with the contacts fixed to the housing. 3. Vibration meter according to claim i or 2, characterized in that the bumper (4) is hollow and designed to accommodate the connecting lines for the individual voice coils.