DE683034C - Device for converting small direct voltages into proportional alternating voltages - Google Patents

Description

Device for converting small DC voltages into proportional ones AC voltages The task of using DC voltages for control processes encounters significant difficulties when using the available DC voltages are very small. Such a case is e.g. B. before when the temperature of annealing furnaces should be kept constant at a desired value and measuring the high Temperatures happens with the help of thermocouples. Since the to trigger the control process Available fluctuations in the thermal voltage are so small that a direct influencing of the control equipment is not possible, one has helped by feeding a galvanometer with the thermal current, the deflection of which be it via photocells, bolometers or directly using drop stirrup instruments, was used to trigger the control process. The detour via galvanometer and Photocell or via galvanometer and drop arm device is disadvantageous in this respect, as only extremely sensitive for the exact indication of the small currents in question Instruments can be used if they are handled properly in rough workshop operation is not guaranteed, and also the whole control system is thereby complicated and expensive. On the other hand, a device has become known in which Thermal voltages are fed to converters via a magnetic amplifier, whereby a constant temperature control can be achieved. This magnetic amplifier consists of four identical iron cores with four windings each. These four cores are connected in series on the AC side, while an auxiliary DC current in two of the Cores flow in the opposite direction as in the other two. Through this Auxiliary currents are periodically saturated the cores, so that on the secondary windings theoretically no voltage can occur if there is no voltage in the primary windings Direct current flows. This arrangement is very stable because it is not movable Contains parts, but it has the disadvantage that the bias DC must be kept constant very precisely, otherwise already in the output circle Alternating currents occur even when the current of the thermocouple is still zero.

Furthermore, a device is known in which a small to be measured DC voltage is fed to a converter, which consists of two mechanically connected to each other coupled coils, which are part of a magnetic in the air gaps DC field, partly one alternating magnetic field generating Magnets are resiliently arranged. In this known converter, the DC voltage is supplied to the coil lying in the DC magnetic field and .- "dig ' transformed alternating voltage from the ° @ a`, ä lying in the magnetic alternating field "' Bobbin removed. The latter coil is arranged so that it is at rest no alternating voltages are induced by the surrounding alternating field. This arrangement is disadvantageous in that it requires a very precise setting of the zero position, otherwise even when the first coil is de-energized in the second coil AC voltages occur.

According to the invention, this disadvantage is eliminated in that the The direct voltage to be converted is fed to the conductor lying in the alternating magnetic field and that the converted alternating voltage corresponds to that lying in the constant magnetic field Head is removed.

In the converter according to the invention, the thermal voltage is a Loop or wire fed into the air gap of an alternating current energized electromagnet is located. Only in the presence of a thermal voltage leads under the influence of the alternating magnetic field of the wire vibrations. Under Assuming some kind of damping, the amplitude of the oscillation will be depending on the magnitude of the thermal voltage. Mechanical is done with the wire mentioned above a second conductor is coupled, located in the air gap of a permanent or a magnet excited by direct current. As a result of the coupling between these and the wire through which the thermal current flows, the second wire also starts to vibrate, urid it becomes one of the amplitude under the influence of the constant magnetic field AC voltage proportional to the oscillation induced, if necessary can be reinforced in a known manner.

Fig. I shows an embodiment in a schematic representation. The wire loop through which the thermal current flows is denoted by i. she is attached to the insulating bridge: 2. The wire loop is on the same bridge 3 attached. By the spring q. mechanical preload is applied to both wire loops granted, with whose help the resonance frequency of the loop system and thus the Sensitivity of the arrangement can be changed by changing the spring more or less is tensioned. The electromagnet excited by alternating current is denoted by 5, in whose field the loop i is located. To reduce the magnetic resistance an iron body 6 can be attached between the two sides of the loop.

The Elektro-2ägnet excited by direct current is denoted by 7. Also in his.: Air gap there is an iron body 8, which is used to reduce the magnetic resistance is used. At 9 and io the one generated in loop 3 is generated AC voltage removed.

The whole system, as shown in Fig. I, can if necessary brought into a dampening medium - verden. Under certain circumstances, it may be sufficient as damping but also the electrical power drawn from loop 3.

Another embodiment is shown in Fig. 2. In this case only one wire i i present, through which the thermal current flows and in which at the same time the alternating voltage is induced. The thermal voltage is applied to terminals 12 and 13 -supplied. The AC voltage can also be taken from the same terminals. The wire i i is pretensioned by the spring 14. The electromagnet excited with alternating current is denoted by 15, the magnet supplied with direct current is denoted by 17.

Claims (6)

PATENT CLAIMS: i. Device for converting small DC voltages in proportionate alternating voltages by means of two mechanically coupled, , in particular loop-shaped conductors, which are part of a magnetic in the air gaps DC field, partly of a magnet that generates an alternating magnetic field, is resilient are arranged, characterized in that the DC voltage to be converted to that arranged in the alternating field and the transformed alternating voltage on that in the constant field arranged conductor lies. 2. Device according to claim i, characterized in that that instead of the two mechanically coupled conductors only a single conductive wire is stretched between the two magnets (Fig. 2). 3. Device according to claim 2, characterized in that the supply of the DC voltage to be converted and the Decrease in the converted AC voltage at the same connection points (12, 13) he follows. q .. Device according to claim i or 2, characterized in that the Tension spring of the ladder is made adjustable. 5. Device according to claim i or 2, characterized in that by a strong excitation of the magnets the AC voltage taken is increased compared to the DC voltage supplied is. 6. Device according to claim i to 5, characterized in that the converter supplied DC voltage is the voltage of a thermocouple and that the removed AC voltage to regulate the temperature monitored by the thermocouple serves.