DE149820C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The electricity meter forming the subject of the invention is essentially one Transfer and development of the ampere-hour meter described in patent specification 152889 underlying principle on a watt-hour meter for direct and alternating current. the magnetic slider magnetizing field from the permanent magnet is generated, this is done here by a current coil. By then having the magnetizing and deflecting current winding switches in the manner of a wattmeter, one is proportional to the watts on the slider Force exerted resp. one gets an electricity meter, provided one by arrangement a switching device initiates a continuous rotating movement.

Now there are electricity meters in which one is magnetized by a central coil Iron core is deflected by a second fixed current system, already known (see German patent specifications 103008 and 129686). The present one differs from these and similar constructions Counter basically because its mode of operation is unipolar. A rotating movement, of course can only be achieved by a corresponding switch in one or the other power system, that's the arrangement and to see the mode of action in its elementary movements as a unipolar, which is at is not the case with the other constructions.

This unipolar arrangement now primarily enables the use of a sheet of iron or a piece of very low mass, which results in a very light movable system and also enables the meter to be used in alternating current systems, which is also not possible with the aforementioned constructions is. Furthermore, the fixed, deflecting current system can be designed as a flat coil, and this results in a very compact, compensatory arrangement and, due to the close proximity of the magnetic slider and the deflecting current coil, great sensitivity, which also results in very low internal consumption of the device. To explain what has just been said, the description of an embodiment may follow (FIGS. 1 and 2). The uniform magnetic field polarizing the magnetic slider m is generated by the circular voltage coil η , in the center of which the slider m can rotate about the axis α. The slider m is under the action of the power system W, which is only indicated schematically in FIGS. 1 and 2 and whose particular design will be discussed in more detail. In order to achieve a uniform rotating movement, the current in the deflecting current system must always run in the same sense, ie either always centripetal or always centrifugal. On the other hand, the entire power system must never be live, as otherwise no torque is generated according to the laws of unipolar induction. That

Strength current system must therefore be broken down into subdivisions and the latter must then be successive be switched on. The subtle forces at work in an electricity meter Because of this, only very weak currents can be switched, and therefore the Subdivisions can be placed in parallel to form a permanent shunt. The circuit and Switching of these subdivisions can

ίο then be done in the same way, as indicated in Figure 4 of Patent 152889.

As far as the practical implementation of the power system is concerned, it can be done once take place in the form of curved, circular solenoids (see. Fig. 3 and 3a), wherein the radial conductors running in one plane cause the deflection; or alternatively, the deflecting current system is made up of four each occupying one quadrant semicircular coils together, which are wound in a fan shape (see Fig. 4). Combine this appropriately Coil ι and 2 to a single, also 3 and 4.

The switchover is therefore carried out in the power system. Now is but it is also possible to have a rotating movement by switching over in the voltage system to bring about, and the particular advantage here is a very simple one Execution of the power system and the elimination - switching in the same. As a result, you can also use up to

Refrain from using shunts for large currents.

The power system has to be at least in order to achieve any movement have two sub-divisions. Let us therefore take two subsections for the sake of simplicity on, this means that the power system expediently manufactured as a flat coil in one half stream of one direction, e.g. B. centripetal, leads in the other stream of the other direction (see Fig. S) - '

When the high and low current systems are excited, the slider will therefore adjust itself in such a way that, depending on the direction of the current, it is below one of the poles of the high current system, that is to say the dividing line between the two current layers (see FIG. 5). At this moment the voltage coil is switched over and, due to the different polarity, the slider continues to rotate. There are obviously two dead spots here. If the counter happens to have stopped in the position in which the switching of the voltage coil is about to take place, i.e. in which the latter is currently de-energized, the slider is therefore de-energized, then when the counter is switched on, the high-voltage current will hold the slider in this position Apparatus does not start. There is a simple means of preventing this. An elongated coil of a few turns is arranged above the power system, which generates a field perpendicular to the field of the power body and mainly with a. Parts of its winding form a layer of current bridging the poles NS of the power system. In addition, its winding plane can run parallel or perpendicular to that of the power system. In Fig. 5 the same z. B. assumed as a flat coil in a parallel arrangement to the power system. If you send a current in a certain direction in the same direction, depending on the direction of rotation of the counter, this auxiliary winding ensures that the slider can never stop in this central position directly under the poles NS , but when the counter is switched on, it immediately shifts in the sense of the normal direction of rotation learns. As soon as this shift occurs slightly, the voltage coil is switched on and the apparatus continues to work quietly. The auxiliary coil can be excited both by the voltage current, i.e. in series with the voltage coil, and by the high current, i.e., as assumed in FIG. 5, in series with the high voltage system, the latter arrangement being the more appropriate for various reasons is.

This auxiliary winding has no influence on the remaining rate of the counter because it acts as much accelerating as it is inhibiting during a full revolution. These Auxiliary winding is in contrast to the ampere-hour meter described in patent specification 152889 Not dispensable with the watt-hour meter at hand, even if the power system is more like two Subdivisions there. It is therefore best to stick to two subdivisions.

As far as the necessary switching is concerned, it differs depending on how one is in the High or low current system switches. If you switch over in the high-voltage system, so can do the same, as noted above, in the same manner as in Figs. 3 and 4 of the patent cited several times take place.

If, on the other hand, the switchover takes place in the voltage system, then with each switchover " the current direction "in the voltage coil can be changed, and this makes in the usual switching of a commutator requires more than two contacts.

In the case of an electricity meter, every contact now reduces safety and

increases the harmful friction. Hence this change of current in the voltage coil with as few as possible. To accomplish contact points, one turns expediently under Use of the switching device shown in Fig. 4 of patent specification 152889 in Fig. 6 of the accompanying drawing reproduced circuit.

The commutator consists of the inner closed contact rings s and the two outer semicircular .Contact pieces c. On 5 and c , the contact wheel drags d. The shunt circuit connecting the mains lines LL now contains, in series connection, the permanently switched on series resistor r, which throttles off most of the mains voltage, as well as the resistors W ₁ w. _{2 of} the same size. The further combination of W ₁ w. ₂ and the voltage coil η of the counter with each other and with the switch shows the scheme of Fig. 6. It is hereby achieved that to the circulation of the contact Röllchens d with said rings s associated end of η soon to the outer end of W _x , soon to which W _{0 is} applied and this results in a change in the direction of the current in η. Because the other end of η is permanently fixed, the current change can be achieved with only two contacts. Furthermore, this circuit prevents sparking at the contacts, in that the voltage coil is permanently parallel to one of the resistors W ₁ w _%. Now, however, it is possible, by using this circuit to further reduce the friction occurring when the current is switched, to make a change in the overall arrangement of the movable system which substantially reduces the friction occurring in the entire apparatus.

Instead of the magnetic slide in FIG. 1, which is fixedly connected to the axis, a type of magnetic roller can also be used (Fig. 7) which is arranged in the following way. A number of thin sheet iron disks e are lined up and fastened on a thin axis. The ends of the axle protruding on both sides of the roll formed in this way from sheet iron disks are firmly connected and each carry a small wheel T ₁ r ₂ made of metal. This magnetic roller is now, as can be seen from Fig. 8, with its two Rd

Cog

on two rings sc from anQ

_{1 2} g

approximately triangular cross-section set, which are arranged on the coil wall of η and a crosspiece g concentric to the axis α . While s now forms a full ring, the inner ring c is cut open in two places or. the gap filled with insulation material. Both guides are now η s and c with the coil voltage in the same manner as in Fig. 6, the contact pieces and the resistors w W ₁ s, and c. _2, respectively. If electricity is now sent to the meter, the magnetic roller continues to roll on the guide rings s and c under the influence of the high-voltage system. At the moment in which the roller passes the pole NS (see Fig. 5) of the power system, the wheel T ₁ goes from one half of c to the other; This causes a current change in η and the game continues.

The sliding piece, which is designed as a magnetic roller, simultaneously takes on the functions of the contact roller d of the previously assumed special commutator.

The transmission of the movement of this magnetic roller on the axis takes place in such a way that a light, z. B. made of profiled aluminum sheet frame R (Fig. 7), which is firmly connected to the axis, which includes _{protruding ends of the axis of the magnetic roller via the wheel T 1} r ₂ with a slight margin and is thus taken from the roller.

The work done by the counting motor is consumed in a known manner by a magnetic eddy current brake and the rotation of the axis α by means of worm and. Gear wheel transferred to a counter with jumping digits.

The advantage of the above-described arrangement of the magnetic roller lies in the Application of rolling friction while reducing the weight of the moving one System, which means a reduction in bearing friction. Then the functions of the magnetic slide combine and the special commutator, making the latter unnecessary.

Due to the small mass of the magnetic slider, the counter can do the same Way to be used for direct and alternating current.

Instead of the arrangement previously assumed and shown in the figures, in which if the slider rotates in one plane, the same can also be done with an appropriate design of the strong and weak current system describe a cylinder jacket during its movement without affecting the Principle something is changed.

Claims (1)

Patent Claims: I. Electricity meter for direct and alternating current, in which a transversal magnetized slider is located in the uniform field of the same magnetic netizing fixed current coil moves and from a very close and parallel to its plane of rotation arranged second, also fixed current system is deflected in a unipolar effect, wherein a continuous rotation by switching in one or the other of the power systems connected in the wattmeter circuit is brought about. ίο 2. Execution of the described under I. Electricity meter, characterized in that the magnetizing the slide The current system is designed as a voltage coil, the other as a high-voltage system, the latter being made of two or more subdivisions, made of curved solenoids (Fig. 3) or fan-shaped flat disks (see Fig. 4) consisting, is produced, all of which become one traversed by the main stream Resistance are parallel and are connected to the same one after the other by the slider. 3. Execution of the electricity meter described under 1., characterized in that that the power system is permanently switched on by a two-pole or multi-pole Flat coil is formed while the current in the voltage coil with the movement of the slider so often is switched when the power system has poles. 4. Execution of the electricity meter described under 1., characterized in that that the dead point occurring in the arrangement described under 3 is due to a ■ in series or parallel Auxiliary coil connected to the consumption circuit is eliminated, which generates a field perpendicular to the main field (Fig. 3) 5. Execution of the under 1. described Electricity meter, characterized by the application of the known Resistance circuit in which the middle of two resistors connected in series or electromotive forces with the interposition of the relevant power system in which the power is to be switched to one End of the switch is performed, which the power system soon to the one End, soon to be placed on the other free end of the resistors in order to effect a switchover by means of a single contact, on electromagnetic movement apparatus (motor electricity meters) for the purpose of simplifying switching and reducing sparking. 6. Execution of the electricity meter described under 1., characterized in that the magnetic slider is formed into a magnetic roller which runs by means of two small wheels (i \ r. ₂ ) (Fig. 7 and 8) on two raised rings (sc) , which are arranged concentrically to the axis and, in that one consists of two electrically isolated halves, are connected to the coil η and the resistors (> v _L W ₂ ) in the same way as the contact pieces fs c) of the commutator in Fig 6. 7. Execution of the electricity meter described under 1., characterized in that in the arrangement described under 6. the magnetic roller is formed from several sheet iron disks lined up on a thin axis, the movement of which is carried out by a frame R encompassing their axis ends with little play the axis is transferred. 1 sheet of drawings.