DE191516C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- Yes 191516 CLASS 21 e. GROUP

Patented in the German Empire on April 20, 1907.

Motor electricity meter with permanent magnet and one in its field Anchors show up due to the friction in the bearings in the counter and on the contact brushes too little if the stress is low, and there has been no remedy in the same way up to now Like the auxiliary coil used in watt-hour meters, an additional torque of sufficient strength with low stress

ίο could evoke the influences of the Eliminate friction on the indications of the meter.

Attempts have been made repeatedly, using turns around the permanent Magnets or arranged on a yoke piece of the same and flowed through by the consumption current were to change the field of the magnet according to the friction factors; but the effect of such compensation windings was mostly very little or the effort of copper to achieve the intended effect is very large. Also could on this In this way, additional torque cannot be achieved with a low load.

The subject of the invention described below is a device by which it is possible, so to speak, to use part of the torque caused by the higher load to be kept in reserve and to have an additional effect in the case of the lower loads to compensate for the friction.

In FIG. 1, M is a permanent magnet, in the field of which the armature connected in parallel with the resistor W rotates. B, B ¹ are the brushes, K is the commutator, P a pole horn, which is polarized by the permanent magnet. The brushes are attached to the double-armed lever H , which carries the spool S at one end. The fulcrum of the lever is at D. In Fig. 1, the spring F forms a feed line to the coil 5 for the current from the resistor W. The end of the coil is connected to the brush B ¹ , while the brush B by a thin one Spring wire is connected to the other end point of the resistor W. The coil S and the. Anchors are thus connected in series. The ratios are chosen so that with a very weak current, e.g. B. ι percent of the maximum current, the coil 5 has no effect on the lever H. The lamellas of the commutator run helically and the pitch of the screw can be dimensioned in such a way that the commutation position for the armature changes the more the higher the brushes through the coil S rest on the commutator.

If the maximum current flows through the resistor W , the coil 5 pulls the lever H with it until the stop piece rests on the stop screw A. This gives the brushes a certain position on the commutator and the attractive force of the coil can easily be made large enough to hold the lever H in the stop position when the current in the resistor W has dropped to half the maximum load, for example. Above these load levels, the armature torque is only dependent on the current flowing through the armature and on the constant field of the permanent magnet.

.2. Edition, originally published on June 16 igog.)

Claims (2)

If the current in the resistor W still falls below 1Z2 of the maximum load, the friction begins to have a disruptive effect on the data in a normally designed counter, which becomes stronger the further the load drops. In the case of a counter that is provided with the device described above, the armature now receives an additional torque the further the load decreases. This arises from the fact that from a certain (e.g. 1Z2) load the coil 5 slowly goes upwards when the current in the resistor W drops. The brushes B, B1 come in a lower position to the commutator, and as a result of the helical lamellas, the mutual position of the lines of the armature force field to the lines of force of the permanent magnet is more favorable in these positions, or by shifting the commutation position by a corresponding amount The torque held in reserve of the pole pitch now comes into effect, and it is easy to see that by suitable dimensioning of the acting parts the calibration curve of the meter can be kept constant within 1 percent for each point of load without difficulty. This device is particularly advantageous for ampere-hour counters in order to achieve a safe start-up with the lowest loads, and as a result the number of turns and the weight of the armature can be reduced and the current flowing through the armature can be kept smaller, which means that the commutator is significantly spared. Fig. 2 shows another type of circuit of the coil 5; the same is connected in parallel to the armature in this case. Pa ten τ-A ν Proverbs: 1. Ampere-hour meter with armature rotating in a permanent magnetic field, thereby characterized in that one of the consumption stream or a part thereof Auxiliary coil through which it flows so movably arranged over a permanent magnet is that it changes the commutation of the armature, for the purpose of part of the normal in the case of higher loads, to keep the torque developed by the anchor in reserve, which acts as an additional force in the case of smaller loads comes. 2. Ampere-hour meter according to claim 1, characterized in that the lamellae of the commutator run helically and the brushes sliding on the same by an electromagnetic coil 'in moved in the longitudinal direction of the slats. 1 sheet of drawings.