DE517486C - Economy circuit for load testing of high-frequency generator systems, in particular of tube transmitters - Google Patents

Description

When stress testing large high-frequency systems, especially large ones Tube generators, the difficulty often arises that the test site does not have has a sufficient source of energy or the full amount of energy is too expensive.

The invention now makes it possible to eliminate this difficulty, namely by that the principle of working back to artificially load a high-frequency system is used. This is done according to the invention in such a way that the high-frequency delivered by the high-frequency system Usable alternating current via a frequency reduction or rectifier arrangement, in turn, of the primary supply current source or the feed circuit of the tube or a feed pre-circuit. An embodiment according to the invention for the artificial loading of tube transmitters is shown schematically in Fig. 1, in the event that the feed energy to cover the losses when testing a tube transmitter is a low or medium-frequency alternating current network.

The low or medium frequency alternating current network η, η feeds a tube generator R via a transformer T ₁ and a rectifier G a transformer T _{2 is connected} to the rectifier G in parallel with the main transformer T ₁ . The blocking chokes DD are used to block the network or the transformer T ₁ from the high frequency, and the blocking capacitors CC are used to block the transformer T ₂ from the low or medium frequency of the network . The correct size of the high-frequency voltage J ₂ is set by a suitable transmission ratio or by variable coupling of T ₂ or of the antenna transformer T _a , the correct phase by regulating C _a , L ₀ .

Since the antenna frequencies are generally high, T "can also be carried out without iron.

Of course, you can also use this method of working back in a similar way in the Use the case if a direct current network is available to supply the transmitter.

Another embodiment is shown in Fig. 2. This relates to a high-frequency system with frequency transformers.

*) The patent seeker stated as the inventor:

Mendel Osnos in Berlin.

It is assumed here that the transformers can be separated into two approximately equal groups or parts. Is z. B. The medium or high frequency energy supplied by an energy source is multiplied by a frequency transformer that has two spatially separated iron cores or two winding groups with mutual scattering ^ so one will ίο separate these parts from each other and also the other circuits of the system to test the load of the system disassemble into two approximately equal parts. One part of the economy circuit then consists of half T of the frequency converter, the tuning elements L ₁ , C ₁ , L ₂ , C ₂ , L _a , C ₁₁ and the coupling transformer K, and the other part consists of the second half T ' of the frequency transformer together with tuning elements L ₁ , C ₁ , L '", C ₂ , L' _a , C ₀ and coupling transformer K '. The output circuit III of the first part of the system is connected to the input circuit III 'by coupling coils K _2.

The frequency supplied by the energy source η, η to the primary circuit I is increased by the frequency converter T and the multiplied frequency is transmitted from the secondary circuit II via the coupling transformer K to the output circuit III. From here, the power is returned to the first part via the coupling coils K ₂ and the circuits III ', ΙΓ, I', the frequency converter T now transforming the higher frequency of the circuit II 'back into the lower frequency of the energy source in a known manner . The system is fully loaded here, but the energy source η, η only has to cover the losses of this system.

Fig. 3 shows a similar economy circuit for a transmitter system fed by a high-frequency machine, but the losses of the high-frequency machine can also be measured. Usually high frequency machines have two identical rings of alternating current windings M, M '. It is therefore best to have one half of the machine M work as a generator on half I, II, III of the system and, as in the previous embodiment, the energy from circuit III via circuits ΠΓ, ΙΓ and Γ after it has been reduced by means of frequency converter T. * trace back to the primary frequency of the winding ring M 'of the machine as a motor. Here, the load conditions of the two parts of the system are adapted to one another by setting the variable coupling K _{2 appropriately.}

In order to obtain the correct phase relationships, in addition to the changes in the coupling and tuning means, the two alternating current rings M, M 'of the machine can also be mutually adjusted spatially by a suitable angle.

The drive motor P of the high-frequency machine, which delivers full power during normal operation, only has to cover the losses of the high-frequency system including the high-frequency machine M, M 'during the load test.

Claims (3)

Patent claims: 1. Economy circuit for load testing of high-frequency generator systems, in particular tube transmitters, characterized in that a more or less A large part of the high-frequency useful power is transferred to the primary via a frequency reduction or rectification system Feed current source or a feed pre-circuit of the generator is fed back. 2. Economy circuit according to claim 1 for the stress test of tube transmitters, characterized in that the useful energy supplied by the tube generator In turn, via a rectifier arrangement, the feed line of the tube generator flows in itself. 3. Economy circuit according to claim 1 for load testing of machine transmitter systems with frequency converters, characterized in that the one alternating current winding ring of the high-frequency machine The extracted energy is fed to one half of the high-frequency system, which is divided into two parts is transformed there to the usable frequency and from the output circuit this Half is transferred to the other half of the high frequency system, which the useful frequency is reduced back to the primary frequency and the other alternating current winding ring of the machine 10.5 as a motor feeds. 1 sheet of drawings