DE225937C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 225937 CLASS 21 e. GROUP

MAX STRELOW in BERLIN.

Patented in the German Empire on September 11, 1909.

See Wright to measure the maximum load in electrical systems Tariff is required to measure the average load in a given time and the Once the largest value has been reached, it can be recorded on a counter or readable on a scale. After that, it is by no means necessary to take the measurement at certain time intervals to start over as long as the

ίο Load still below that already registered lies. In patent specification 137115, class 21 e, describes how the maximum load can be measured by means of motor counters. This is done there in such a way that the counter has a second counter from time to time drives with the maximum pointer; for compliance with the time intervals is according to the procedure a timer is always required. Nevertheless, the maximum pointer is now on stops after the highest value has been reached, the drive of the second counter begins always anew even with the smallest loads. This measurement therefore does not fully correspond to the Wright

see tariff, as thereby z. B. the overload of a plant to twice the value of the already measured is not registered at all, provided the overload is only the time a measuring period, usually 15 to 60 minutes, and the decoupling of the Maximum counter falls in the middle of this time period. Since such overloads repeat frequently in a system and can also be brought about easily at will this measuring method will not be sufficiently accurate in certain cases.

The invention has a method for measuring the maximum load in electrical systems to the subject, whereby it is not necessary to always start the measurement again allow.

According to the invention, the measuring device, ζ. B. a motor counter to advance the Maximum counter or the pointer used and at the same time, one on the measuring device to generate self-acting counterforce or an already existing counterforce enlarge it or bring it into an effective position. The effect of this counterforce must become larger with increasing load, so that the measuring device after a certain time, z. B. 15 minutes by which it is brought to a standstill. The pointer deflection then reached corresponds to the mean load during these 15 minutes. The measuring device remains now out of action until a greater load occurs, then the torque of the counter must be greater than the counterforce and the pointer keep moving until again Torque equals counterforce. To

Reading the pointer deflection, e.g. B. monthly, when moving the pointer back to Zero to cancel the counterforce in whole or in part, so that the measurement can begin again can.

It is essential for the invention that the

• The counterforce increased by the measuring device brings it to a standstill. This results in the advantages that the measurement of the maximum load is independent of the consumption measurement Can be run a special time. knife with periodic uncoupling in Elimination occurs, thus eliminating clutch errors at the same time. Since a measuring device after

the invention only works with overloads, so its service life is much longer than those of the known arrangements in which the timepiece rotates continuously and z. B. per Day makes about 100 uncouplings, regardless of whether the meter is loaded or not.

A measuring device according to the invention is therefore used for consumption measurements in watt hours not determined.

The counterforce can be generated in different ways, but its effect on the measuring device must always be the same. The simplest arrangement for generating a counterforce acting on the measuring device is shown in FIG. 1 of the drawing. Thereafter, the counter α tensions a spiral spring b as it is handled, which finally becomes so strong that it brings the counter to a standstill. However, this arrangement is ruled out for most practical cases, since the spring z. B .. with a torque of the counter of 5 cm / g and a number of revolutions of 40 per minute would have to be disproportionately strong. The arrangement could at most be used for measurements of the maximum load within very short times, e.g. B. up to 2 minutes. '
According to the invention, the counterforce is therefore generated or increased by a slowly moving axle, while it acts in a braking or damping manner on a high-speed axle or on the armature itself. It is therefore possible according to the invention to spread the measurement over any desired time. The counterforce can be kept very small, in particular if it acts directly on the armature or on an even faster axis driven by it.

Fig. 2 shows an arrangement for measuring the maximum load according to the invention. The axis α of the counter tensions the spring b, which rests on the stop c, and at the same time moves the pointer d either directly or through the intermediary of the driver d _v

With each revolution of the axis α , the nose e touches the spring 5 and thereby gives it a movement at right angles to the tensioning direction. The movement of the spring caused by the contact with e is only small, and since the spring has a certain internal strength, the nose e will practically tension the spring b in the opposite direction. After a certain time, the spring b will now be pulled up so far that β is no longer able to perform a counter-tension. Then the counter stops, until the counterforce is lifted or the torque of the counter increases as a result of its increased load. Then the counter with the pointer runs forward until equilibrium between torque and spring tension occurs again. With a suitable translation, this point in time can be postponed at will.

FIG. 3 shows an arrangement similar to FIG. 2, but with a helical spring δ. According to FIG. 4, the counterforce is produced by a continuously rotating spiral spring. The counter axis α drives the wheels f, g, h and i . The wheel f is fixed, while the radiator is loosely arranged on the axis k ; The spiral spring b lies between the two wheels. The translation between f, g, h and i is chosen so that the wheel i lags behind or leads by a small angle with each revolution of the wheel f , so that the spring b is stretched a little with each use until the tension is so great is that the counter thereby reduces its number of revolutions and finally stops. The differential movement between the axis k and the wheel i can. can be transferred directly to the scale and pointer, so that a maximum pointer in the simplest form is obtained, with clutch springs and unnecessary movements of the meter being avoided in the event of small loads.

Instead of using a spiral spring for the counterforce, one can, as FIG. 5 shows schematically, slowly switch on a coil I counteracting the armature or, according to FIGS. 6 and 7, slowly bring an already switched on winding into the effective position. Instead of a counter-winding, iron, copper or aluminum pieces can also be used for the counterforce in Ferraris measuring devices by adjusting them in such a way that they cause counter-effects through asymmetry or additional phase shift. Finally, a weight can also be used, the lever arm of which is increased with increasing load and increasing number of revolutions until the counter comes to a standstill.

The method according to the present invention

application is applicable to counters for every type of current, as well as to oscillating or clock counters.

Claims (1)

Patent claim: Method for measuring the maximum load in electrical systems, independent from the consumption measurement, using a counterforce acting on the measuring device, which with increasing Load is greater, characterized in that this counterforce the measuring device after certain times to Brings to a standstill. For this purpose ι sheet of drawings.