DE294115C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

It is known to use so-called magnetic magnets for the purpose of temperature compensation Equip shunts made of a magnetic material of temperature dependent Permeability exist (e.g. nickel steel). The essence of this balance is made by its designation as magnetic Shunt clearly determined; it consists in that the magnetic flux is divided into two parts, one of which is the armature to be induced (disc, Drum, etc. made of aluminum, copper or the like) interspersed, the other, however, by the shunt through, so without having an effect in the anchor, parallel to the first, so to speak is short-circuited. If, for example, a temperature increase occurs, the magnetic resistance of the increases Shunt too, and a corresponding part of the ineffectively sucked off by this Lines of force are forced into the effective flow and also act on the anchor. So is the electrical conductivity of the as a result of the same increase in temperature Anchor has become smaller, more lines of force are now cut for it, and at corresponding dimensions of the shunt can in this way be achieved by induction and reaction torque of the armature are kept constant. The same consideration applies in the opposite sense to a decrease in temperature.

The major disadvantage of this compensating device is that a considerable loss of effective lines of force, which experience has shown can be around 35 percent, with in Purchase must be made.

In contrast, means the temperature equalization according to the present invention a considerable advance in that all the lines of force of the magnet remain usable. Compared to the known shunt method, the innovation aptly referred to as the main circuit arrangement. The basic idea is that, at 4-5 Changes in temperature mean a shift in the point of application of the resultant from the force line sections to effect on the armature with respect to its axis of rotation. . ■

So, of the two factors that make up a torque, becomes essential the lever arm changed depending on the temperature.

The invention will be explained in more detail using three application examples.

Fig. Ι shows the compensation device on a brake magnet with disc armature in an electricity motor meter. The pole ends p of the magnet m are bent together in such a way that the brake disc s, which is supported so that it can rotate easily with the axis b, can move freely through the small gap. According to the invention, compensating pieces made of magnetic material of temperature-dependent permeability are attached to the poles on the side facing the axis of rotation of the armature. If the temperature rises, i.e. if the electrical resistance of the armature rises, the permeability of the

gen appropriately matched compensation piece χ , and the result is that the lines of force are pushed outwards, away from the pivot point of the armature, and now come into effect with greater density on a larger lever arm. This compensates for the reduced electrical conductivity of the armature, which would result in a lower torque, i.e. the torque in each case

ίο kept constant. Likewise, the . The point of application of the mean force is shifted towards the pivot point when the temperature drops, the greater conductivity of the disc ,? corresponds, and so the same effect the respective maintenance of the torque achieved.

As shown in the schematic drawing, the compensating piece in the magnetic pole inserted to. Rather, it can possibly be easier to the side the poles are applied and attached to it in any way. It remains the same within the scope of the invention if, instead of both poles, only one of them is connected to the Compensating piece is provided.

Fig. 2 shows the use of the innovation on an eddy current tachometer with .Scheibenanker. The magnet is denoted by m , the lines of force of which are closed by the so-called return body r and on their way penetrate the disk s rotatably mounted with the axis b. Set in rotation, the magnet tends to take the armature with it and generates a torque against the spring f , which is a measure of the rotational speed of the driving axis α . The poles are here again according to the innovation with the compensating pieces χ made of magnetic material with positive temperature coefficient _: equipped on the sides to the armature axis. The mode of operation is the same as that described in FIG. 1. In the event of temperature changes, the lever arm of the acting force also changes here and thus switches off the influence of the lower or higher conductivity of the armature for the eddy currents caused by the temperature.

Fig. 3 illustrates the new compensation method on an eddy current tachometer with a drum-shaped display body, the jacket of which is conical. The letters denote the same apparatus parts as in Fig. 2. The mode of operation of the compensating pieces χ is also the same.

In the two application examples according to FIGS. 2 and 3, instead of the return body r , a corresponding magnet with or without a compensating piece could also be arranged, which rotates with the magnet m and faces it with opposite poles.

As can be seen from the applications, it is essential that the compensating pieces x are arranged in such a way that they do not suck out any lines of force before the armature is enforced, but are instead switched on to the effective magnetic flux of lines of force and shift its center of attack when the temperature changes in accordance with the changing armature conductivity.

Claims (1)

Patent claim: Temperature compensation for magnet-electric apparatus by means of magnetic Material of temperature-dependent permeability, characterized in that the compensation pieces at the poles of the effective flux of lines of force are penetrated and are to the axis of rotation of the armature so that on this in the event of temperature changes the point of application of the resultant from the force line sections is shifted with respect to the axis of rotation and thereby the torque is kept constant in each case. -: 1 sheet of drawings.