DE274289C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 274289 CLASS 21 c. GROUP

Patented in the German Empire on June 4, 1913.

The invention relates to automatic control devices and is in particular for Generators rotating at different speeds, like those used in car lighting systems Find use in which an accumulator battery supplies the power for the lamps, if the generator is with runs at a slow speed or is at rest.

ίο According to the invention is a current regulator provided in order to keep the current supplied by the generator constant until the Voltage of the system has reached the full charge voltage of the battery. At this stipulated Voltage is an auxiliary control arrangement, preferably from a compressible Rheostat exists, shunted to the generator field. The resistance of this Auxiliary regulator is regulated by a coil, each dependent on the voltage of the system is affected.

The effect of the current regulator is that it works to increase the current for charging of the battery. The consequence of this is that when the battery is nearly full is charged, the voltage of the generator must increase in order to obtain the full charge. However, once the battery is fully charged, the auxiliary regulator performs a decrease in the higher Tension and then maintains an even tension, which, however, is too low Has value than that a charging current for the battery could result.

The relay provided for this purpose, under the influence of voltage, has the effect of doing this the circuits and control of the compressible parallel resistance to the field in various ways also forming the subject of the invention.

The drawing illustrates the subject matter of the invention.

1 to 4 show schematically various circuits according to the invention, while the

FIGS. 5 and 6 represent the combined switch and compressible rheostat by themselves.

Fig. 1 shows a variable speed rotating generator, the an armature 1 and a field winding 2 has. A compressible rheostat 3 is usually located in series with the field winding and is regulated by a coil 4 connected to the generator is in series, so is influenced by the current. The rheostat 3 is controlled by an angle lever 5 affects, which is usually held in such a position that it increases the resistance of the rheostat reduced to a minimum. A buffer device 6 influences continuously the action of the bell crank. A second compressible rheostat 7 is shunted under certain conditions

Field laid. This rheostat rests on the piston 8 of a voltage coil g, which is parallel to the generator lines. When the piston 8 is in its normal position, it creates a short circuit around a resistor io, which is determined in terms of size and in series with the field, via contacts ii and 12, and when it is in the raised position, the core opens

ίο this circuit and closes a circuit between the rheostat η and a fixed contact 13, so that the compressible rheostat 7 is switched on parallel to the generator field.

An automatic switch 14 regulates the connection between the in a known manner Generator and accumulator battery 15 and lamps or other power consumption bodies 16, which are in parallel branches to the main lines. This automatic switch is of any known type and has a lifting coil 17, the generator lines 18 and 19 are connected in parallel. He also has a holding winding 20, which is in series with a generator line. The mode of operation of the switch is the well-known to connect the generator to the battery and the lamps when the generator voltage is essentially the same as the battery voltage.

The regulating devices are shown in the drawing as compressible rheostats and has also been described, but it must be emphasized that others as well known control elements can take their place.

If desired, an automatic or other regulator can be used here is specified as a compressible rheostat 21, lie in the lamp circuit to the lamps to protect against excessive voltage.

The control system according to FIG. 1 operates in the following way: If the generator is located at rest, the automatic switch 17 is open and the lamps are switched off Battery 15 powered. Contacts 11 and 12 are closed and the coil 4 is not energized. The resistor 10 is short-circuited and the resistance of the rheostat 3 is brought to a minimum. When the generator starts so its field grows rapidly until the voltage of the generator is essentially the Battery voltage reached, in which case the automatic switch 14 is closed. at If the voltage rises further, the control coil 4 operates in such a way that the resistor 3 is increased and that an effort occurs, the charging current for charging the battery and to feed the lamps through all speeds of the generator and without worrying to keep the increase in the back electromotive force of the battery constant. When a tension is reached, the substantially corresponds to the full state of charge of the battery, the coil 9 is sufficient excited to raise her core 8. This opens the short-circuit circuit around the resistor 10 and the circuit between the rheostat 7 and the contact 13 closed. This creates a circuit which is parallel to the field, produced by the branch point 22 in the field circuit via line 23, rheostat 7, contact 13, line 24 and 25 to generator line 19, and at the same time the resistor 10 comes with these parallel circles and the Resistance 3 to be in series. The resistor switched on in this way and the Effect of said parallel circuit suffice to increase the generator voltage in such a way reduce that the charging current drops practically to zero, the resistor 10 den Rheostat 3, which, as a result of the current decrease in 4, loses its resistance value, supplements, and now the lamps are regulated to constant voltage, the generator is powered by this Point out to constant potential regulated by the coil 9, which is the resistance of the rheostat 7 and in this way diverts more current from the field, always with the particular aim of to keep the voltage constant. In a sense, the battery is under these conditions in a voltage equalization activity parallel to the main line and a constant potential is obtained, regardless of whether the battery circuit is open or closed, and even if the battery circuit is opened accidentally, a get constant tension.

A control device of this type is particularly suitable for high-speed generators, in which the field magnets work with a low strength, under what conditions the machine for the smallest changes in the voltage at the terminal blocks reacted. An inductive circuit, like the field winding, turns out to be when it is connected to a non-inductive resistance, such as B. with the rheostat 3, is in series, especially if such a resistance is high compared to the inductive resistance, as being very sensitive versus the fluctuations of an applied voltage. This characteristic would now be combined with the unsteady condition of the magnetic circuit achieved a fast, accurate and without oscillations Make regulation very difficult at the speeds that vary within wide limits, if you wanted to try that. regulation

can only be achieved by changing the resistance in series with the field. Due to the arrangement of the auxiliary rheostat 7, however, the field winding does not become one inductive resistance connected in parallel, which changes too quickly, leading to oscillation could result in the regulation in which magnetic flux in the generator prevents since every striving for a change that is too rapid is directly linked to the creation an electromotive force in the field winding is counteracted, which one Sends current through the short circuit closed by the parallel rheostat 7,

! 5 which too rapid changes in the flow of Beginning to delay looking. The greater the speed of the generator, the more so the value of this resistance needs less. to be, and as a result will the establishment always more stable at higher speeds than at lower speeds. But also permitted the parallel resistance 7 at reduced voltage, at which the series resistance 3 would no longer regulate so finely due to the reduced excitation current, one now fine and precise regulation to constant voltage.

FIG. 2 illustrates a modified circuit in which the action of the coil 9 is enlarged by arranging an angle lever 26, which when raised of the core 8 produces an increased lifting force in order to compress the rheostat 7. The contact 13 can be omitted, as can be seen from this figure, and at 27 there should be a permanent connection, but with the resistance plates lie so loosely that before the end of the charge there is practically an infinite value of the Resistance results.

FIGS. 3 and 4 show modified circuits, with the application of which further advantages are achieved.
The circuit of FIG. 3 corresponds essentially to that of FIG. 1, but with the difference that a special relay for opening the short-circuit circuit around the resistor 10 and for closing the shunt circuit for the field via the rheostat 7 is provided. This relay is influenced by a voltage-responsive coil 28 which is connected in parallel to the generator lines. The coil 28 regulates the position of a rotatably mounted lever 29 which carries a contact 30 which works together with a contact 31 to regulate the short-circuit circuit around the resistor 10 , and which also carries a contact 32 which cooperates with a contact 33 works to regulate the circuit for the rheostat 7. If the voltage in the system is less than the full charge voltage of the battery, the lever remains in the position shown in the drawing. When the full battery charge voltage is reached, the lever is lifted to its upper position. After the lever has been raised, the circuit acts in the same way as in the circuit according to FIG. 1.

Fig. 4 illustrates a circuit in which another form of the combined Relay switch and regulator is used, whereby it is achieved that a single coil 34 the functions of the coils 9 and 28 in FIG. 3 are fulfilled. The coil 34 is connected to the generator lines parallel and regulates the lever 29 and contacts that are located on the lever, in a manner that of that of the Coil 28 in Fig. 3 corresponds. A movable armature 35 is rotatably mounted by a Lever 36 carried within the sphere of influence of the spool 34 and controls the degree of pressure of the rheostat 7. The circuit connections and modes of operation of the circuit according to 4 correspond essentially to those of the other figures.

5 and 6 illustrate the construction and operation of the combined Relay switch and regulator. The coil 34 has two windings 37 (Fig. 6), which are arranged on vertical poles 38 of a magnet of the usual horseshoe shape are. In addition to contacts 30 and 32, the lever 29 carries the armature 39 (FIG. 5).

The upper armature 35 on the lever 36 is wedge-shaped and works with the beveled Ends of the magnetic poles 38 together. This construction has an effect in achieve a large extent and results in an increase in attraction to the extent that it is the lever moves down. The increasing attraction is said to be the one with the Increase in compression of the compressible rheostat, increasing counter pressure balance.

The upper air gap between the armature 35 and the magnetic poles is made so large that that the lever 36 is not moved by energizing the windings as long as the lower air gap at 39 is open. This causes the upper anchor to be in place and Stay in place to keep the reluctance of the magnetic circuit constant, so that the lower anchor exactly to a certain and fixed tension, which the full Represents the charging voltage of the battery, can be adjusted. Once the lower anchor is tightened is, the reluctance of the magnetic circuit is so significantly reduced that the upper armature 35 is immediately below the Influence of the windings lengthened and caused

is to exert a variable pressure on the compressible rheostat, whereby this is caused to do its regulating work.

The device can easily be brought into such a state as to be different Tensions responds by changing the normal position of the armature with the aid of the adjustable stop 40 for the upper armature and the adjustable lower contacts.

The rheostats used are suitably of the type in which a number of disks made of carbon or similar material in the circuit is switched on, wherein the resistance of the rheostat is determined by the amount of pressure exerted on the Discs is exercised. Are separate contacts from the rheostats to regulate the Rheostat circuits are used, so metallic contacts with instantaneous interruption Find use. Repeated working of such contacts does not cause any burning of the contact surfaces with the oneself resulting fluctuations in contact resistance and effective air gap. Consequently the setting of the system is not affected by continuous use. the Advantages of using such a relay and regulator in conjunction with car lighting systems can be seen clearly when looking at the one such system actually existent conditions. Suppose it is a 30-volt system with 16 lead-acid battery cells, this is the full charge ratio of the battery reached when the voltage of the system is approaching 42 volts, however is the voltage at which such a battery compared to the main line just comes into voltage buffering state, about 35 volts. When using the described regulator construction now gives the possibility to adjust the lower armature in such a way that that it responds at 42 volts, which would be enough to power the rheostat to be put into operation as long as the lower air gap is open. Once the lower anchor is raised and the lower air gap is bridged, the upper anchor enters the area of influence on and can be adjusted to get around 35 volts in the system. To this With this regulating device it is possible to have a single normally energized To use a coil, which prevents the voltage regulator from working until the full charge voltage of the battery is reached, after which the regulator starts operating automatically comes to get the correct voltage in the system at which the battery is opposite the main line is in the voltage buffering state.

Of course, the above statements are only intended to give an example of the invention, to make their essence clear. However, without deviating from the essence of the invention, manifold changes are made, both in the circuit itself and in the Construction details.

Claims (5)

Patent-to sayings: 1. Control device for a working with battery, with strong variable speed driven shunt generator, characterized in that when the battery is fully charged, which in a known manner with constant current under current influence of a series resistor (3) to the field winding (2) is effected, a control resistor (7) is connected in parallel to the field winding, which occurs under the influence of the generator voltage, for the purpose of operating the generator even when the voltage is reduced after a full charge in a finely graduated manner and quickly without pendulums at constant tension to regulate further. 2. Control device according to claim 1, characterized in that at the same time with the parallel connection of the resistor (7) an invariable resistor (10) in Series is switched with the series resistor (3), which is almost ineffective. 3. Control device according to claim 1 and 2, characterized in that on the lower end of the core of a coil (9) influenced by the voltage, the current circuit device (11, 12) for the invariable resistance (10) and at the top End of a resistance that can be changed by pressure • stand (7) is arranged, which when lifting the core by the coil (9) against a fixed contact (13), and thereby initially the parallel connection of the control - Resistance (7) to the field and, when the core is raised further, its regulation is effected will. 4. Control device according to claim 1 and 2, characterized in that a two-armed lever (26, Fig. 2) on its no longer arm, on which also the core a voltage coil (9) engages the current connection device (11, 12) for the invariable Resistance, and the other shorter arm directly reacts to a resistance that can be changed by pressure (7) works. 5. Control device according to claim 1 and 2, characterized in that one off two magnetically separated, wound Cores of existing voltage relay (34, magnetic bridge (39) to the relay cores Fig. 4) affects two anchors, of which, moved up, so that now the other the one (39) when tightening the switching on 'armature (35) under the reinforced magnetic of the invariable resistance (10) and ^; see effect of the relay is attracted the activation of the parallel control resistor and the control of the parallel resistor Standes' (7) causes and at the same time causes a j. 1 sheet of drawings. BERLIN. PRINTED IN THE REICHSDRUCKEREI.