DE3941055A1 - Low-ripple regulated current supply circuit for magnetron - derives smoother output current from rectification of negative-going half-cycles of three=phase mains voltage - Google Patents

Abstract

Three transformers (30, 32, 34), either ferroresonant or with high stray reactance, have prim. windings connected to a three-phase supply of e.g. 208 V 60 Hz, and sec. windings via DC blocking capacitors (36, 38, 40) to half-wave voltage-doubling diode circuits (42, 50; 44, 52; 46, 54) which supply the cathode of the magnetron. The three-phase arrangement produces a load current characteristic which never falls to zero between peaks occurring at the rate of six per cycle, but maintains a positive value at all times. The redn. of ripple makes for a narrower range of magnetron output frequencies, so that it can be tuned more easily to e.g. 2.441 GHz. ADVANTAGE - Ripple is reduced considerably with more current variations per cycle in comparison with two half-cycles of conventional circuit.

Description

The invention relates to an energy supply scarf device for feeding a magnetron and in particular a Circuit, with the help of which a regulated output value with low ripple can be achieved.

In US-PS 41 75 246 is a power supply circuit described for a magnetron, sometimes as a double half is called wave doubler. This circuit is in Compared to previously used circuits advantageous because using two relatively inexpensive transformers Scattering reactance makes use of what, in contrast to a large stands and much more expensive transformer; Furthermore it generates a magnetron peak current that is not greater than when using a single transformer current is coming.

The circuit according to US-PS 41 75 246, however, has the after part that the ripple of the load current is larger than desired  can be. Because the circuit is a double doubler circuit it generates two half cycles of the load current per period, which rise to a peak and then decrease to zero sink.

The considerable ripple generated by the Doppler circuit speed component causes the magnetron instead of a exactly matched spectral output signal a blurred Frequency band generated. It can also be of considerable value of the peak current to an early failure of the magnetron due to changes in vibration range.

According to the invention, a three-phase half-wave chip Proposed doubling circuit, in which the above he mentioned disadvantages are avoided. Because of the overlay of three vibrations, each 120 ° against each other are offset, provides the trained according to the invention Three-phase half-wave doubler circuit a regulated Load current with a much smaller ripple compo nente that does not have as high a peak value as that according to the status has the trained circuit and also does not drop to zero. This leads to a sharper ab tuning of the magnetron and a reduced probability of failure Probability due to vibration range changes.

With the help of the invention, an energy supply is thus intended circuit for a magnetron, the one has low ripple component.

According to the invention, a circuit is created in which three separate transformers with high leakage reactance can be used. The primary windings of the Trans formers are in a three-phase circuit with each other connected while the secondary windings over respective Capacitors are connected to blocking diode devices, connected to the magnetron.  

The resulting magnetic current has multiple current deflections in contrast to only two half cycles the circuit according to the prior art, which is a considerable reduced ripple factor with the associated Advantages.

The invention will now be described by way of example with reference to the drawing explained. Show it:

Fig. 1 is a circuit diagram of the circuit according to the prior art,

Fig. 2 is a diagram which is obtained with the circuit of Fig. 1 of the load current,

Fig. 3 is a circuit diagram of the circuit according to the invention,

Fig. 4 is a diagram of the load current obtained with the inventive processing scarf,

Fig. 5 is a diagram over one another by means of the circuit of Fig. 1 shows the obtained load current and load current NEN receive means of the inventive circuit,

Fig. 6, the speed obtained by means of the circuit with the higher waviness output spectrum of the magnetron and

Fig. 7 shows the output spectrum of the magnetron by means of the circuit according to the invention.

The circuit shown in Fig. 1 is disclosed in US-PS 41 75 246. The circuit makes use of two relatively cheap transformers 2 and 4 of the leakage reactance type Ge.

The magnetron fed by this circuit is shown at 6 ; it contains an ano de 8 lying on ground 10 and a cathode 12 .

The secondary windings 14 and 16 of the transformers are connected to one another, as can be seen from the illustration, with their common connection point 18 being connected to ground. The return rectifier 12 and 22 are connected to one another, so that the series capacitors 24 and 26 relate to the polarity points indicated by the polarity of the secondary windings in opposite directions. The anodes of the rectifiers 28 and 29 are connected together to the cathode 12 .

The magnetron current obtained with the circuit of FIG. 1 is shown in FIG. 2. It can be seen that two current loops are obtained per cycle and that the current between these loops drops to zero.

Fig. 3 is a circuit diagram of the circuit according to the invention, in which three mutually separate transformers 30 , 32 and 34 are used, each of which is a transformer with high leakage reactance or ferroresonant transformers. The primary windings of the transformers are connected to each other in a three-phase circuit, and they are fed by a three-phase source, for example a 208 V source with 60 Hz.

The secondary windings are connected to a coating of respective capacitors 36 , 38 and 40 , the other coatings of which are connected to respective diodes 42 , 44 and 46 . The other sides of these diodes are grounded, while between diodes 42 , 44 and 46 and the cathode of the magnetron further diodes 50 , 52 and 54 are inserted.

The circuit of FIG. 3 enables a balanced operation, and it generates a load current curve, which is shown in FIG. 4. As can be seen from this Fig. 4, the three-phase configuration according to the invention leads to a load current with many loops per cycle and with much less ripple than the known circuit. In addition, the current between the loops does not drop to zero and maintains a positive value at all times.

In FIG. 5, obtained by means of the doubler circuit of Fig. 1 curve A and that obtained with the inventive circuit curve B are shown superimposed. The ripple achieved with the circuit according to the invention is significantly lower than that of the known circuit; in addition, there is always a positive value.

The reduced ripple results in a smaller range of output frequencies for the magnetron, making it easier to tune. This is illustrated in FIG. 7, which shows the magnetron spectrum achieved with the circuit according to the invention; Fig. 6 shows the magnetron spectrum, on the other hand, which is obtained with the aid of the known circuit. It can be clearly seen that a much sharper magnetron tuning is achieved by means of the circuit according to the invention, which leads to a more effective operation of a microwave lamp which can be fed by the magnetron.

In addition, smaller transformers can be used for the same performance requirements as in the circuit of FIG. 1. The lower ripple and the fact that the current does not drop to zero leads to less flickering of the lamp in the application mentioned. Since higher peak currents can lead to changes in the oscillation range of the magnetron, the reduced peak values which are achieved by means of the circuit according to the invention lead to a reduction in the problem of changes in the oscillation range.

The invention is here in the context of a special one Embodiment has been described, but is for the One skilled in the art recognizes that within the scope of the invention without wide res modifications and changes to the circuit described can be made.

Claims (5)

1. Power supply circuit for feeding a magnetron with a regulated output current with low ripple, characterized by

• a) three transformers with high leakage reactance, each having a primary winding and a secondary winding with first and second conductors, wherein
  • (1) the primary windings of the transformers are connected together in a three-phase circuit so that three conductors are available for connection to a three-phase source, and
  • (2) the first secondary conductors of the same polarity of the transformers are connected to one another,
• b) three capacitors, one of which is connected to the second conductor of the secondary winding of a respective transformer,
• c) three first diode devices, each of which is connected between the other coating of a respective capacitor and the common connection point of the first secondary conductors,
• d) a magnetron and
• e) three second diode devices connected between the first diode devices and the magnetron.

2. Circuit according to claim 1, characterized in that the magnetron has an anode and a cathode that the common connection point is ground and that the anode of the Magnetrons are also grounded. 3. A circuit according to claim 2, characterized in that the second diode devices to the cathode of the magnetron are connected and that the first diode devices are connected with such a polarity that the Dio the towards the ground, while the second diodes in front directions with such a polarity are connected, that the diodes towards the first diode devices conduct. 4. A circuit according to claim 3, characterized in that the three transformers are separate and separate Are transformers. 5. Power supply circuit for feeding a magnetron with a regulated output current with low ripple, characterized by

• a) three transformers with high leakage reactance, each having a primary winding and a secondary winding with first and second conductors, wherein
  • (1) the primary windings of the transformers are connected together in a three-phase circuit so that three conductors are available for connection to a three-phase source, and
  • (2) the first secondary conductors of the same polarity of the transformers are connected to one another,
• b) three capacitors, one of which is connected to the second conductor of the secondary winding of a respective transformer,
• c) three first diode devices, each of which is connected between the other layer of a respective capacitor and ground with a polarity such that the diodes conduct against ground,
• d) a magnetron and
• e) three second diode devices, which are connected between the first diode devices and the magnetron with such a polarity that the diodes lead to the most diodes.