DE1491382B2 - MAGNETIC RON GENERATOR, IN PARTICULAR FOR HIGH FREQUENCY HEATING - Google Patents

Description

I 491 382

3 4

Drawings shown and are shown below the Emitlersirom of the transistor 12 in one

described in more detail. It shows two-stage DC amplifier with transistors

F i g. 1 a circuit arrangement of a magnet 19, 20 amplified, and the amplified Emiuerstrom

trongenerators, the transistor 12 is in the collector circuit of the

F i g. 2 is a timing diagram. 5 transistor 20 lying magnet coil 6 is supplied.

The one in Fig.! Magnetron generator shown. The transistor 19 contains one in the emitter circles

has a magnetron 1 with a power of approximately inserted negative feedback resistor 21, and the

2 kW for generating UHF oscillations with transistors Ϊ9 and 20 are each with one with the

a wavelength of 12 cm. The anode and the base electrode connected stabilization resistor

The cathode of the magnetron 1 is connected to the output io 22 and 23 yerehen.

terminals connected to a rectifier 2, which is connected to the control circuit 4 described by

the terminals of a three-phase alternating voltage stabilization of the magnetron direct current a considerable

network is connected. The magnetron generator lent a reduction in the fluctuations that occur

forms part of an ip. The figure does not show the power output by the magnetron 1

placed high frequency furnace, being obtained for intermittent 15. When the magnetron DC increases,

running operation in the supply circuit and so increases as a result of the increase in voltage on

Switching off the magnetron 1 serving switch 3 capacitor 10 the emitter current of the transistor 12

is inserted. and thus also the Err.-. ^v ercurrent for the magnet

To reduce the z. B. by Netzspunnungs- coil 6, whereby the magnetic field of the fluctuations caused Är.Jerungen in the 30 magnetron 1 is strengthened. This field amplification acts on the power output of the magnetron 1, the magnetron generator, which is depicted as the magnetron direct current, counteracts a control circuit 4, while, conversely, when the magnetron direct current is reduced with the magnetron direct current connected to the supply circuit of the magnetron 1, the consequent closed control circuit 5. The output circuit of the weakening of the magnetic field the reduction of the control circuit 4 is counteracted by a magnetic coil 6 of the magnetic 25 magnetron direct current. In this way, the system of the magnetron 1 is connected, the fluctuations in the excitation current supplied by the magnetron and thus the magnetic field of the magnet of z. B. several hundred watt trons is controlled by the control circuit 4. To be pushed down to a few tens of watts
When using this control circuit 4, excellent results were achieved in operation by the described preliminary and appropriate magnetron design, but when the magnet system of the magnetron 1 was extensively tested, it was found that ftls formed a separate control coil Magnetic coil 6 the service life of the magnetron 1 meets the expectations together with one shown in FIG. 1 shown schematically was not sufficient, which was due to the fact that provided permanent magnets 7 are formed, the magnetic fields of which mutually support each other briefly when the magnetron 1 is switched on. 35 a peak current flowed through the magnetron 1, the

In the in F i g. 1, an overload of the magnetron 1 caused. Will

the control circuit 5 of the control circuit 4 is switched on by the magnetron 1 by the switch 3,

into the DC feed circuit of the magnetron 1, the magnetic field of the

joined series resistor 8 and a subsequent magnetron 1 only by the permanent magnets in this

Smoothing filter for smoothing out any ripple- 40 supplied, which is only a fraction of the required

Tensions formed. The filter consists of supplying a magnetic field, whereby the magnetron equilibrium

a series resistor 9 and a transverse condenser current has a maximum value. until after one

Sator 10, which is loaded over a relatively high by the time constant of the control device 4

i series resistance 11 to the base electrode of a time delay the magnetic field of the magnetic

Compensating connected transistor 12 is 45 trons 1 by the excitation of the magnetic coil 6 den

is closed. whose emitter circuit assumes normal value for this purpose. The time constant of the

contains a Zcnerdiode Ϊ3. The Basiselek control circuit 4 is in the illustrated embodiment

Itrodc of transistor 12 via a base-emitter example is essentially determined by the time constant

'Resistor 14 connected to the emitter electrode, the smoothing filter 9, 10 and the size of the magnetic

and the supply voltage of the transistor 12 is 30 coil 6 conditioned.

one via a transformer 15 to the alternating In the timing diagram of FIG. 2, the push-pull rectifier connected to the magnetic voltage network has the Her, represented by the curve α , with the diodes 16 and 17 and one on the course. At the switch-on time T ₀ , the magnetron output circuit of the rectifier connected direct current has a maximum value, e.g. B. the three-Cilättungskondensator 18 removed. 55 times de, normal value / ₀ , and is only through

If, in the comparison just described, the effect of the control circuit 4 after a circuit, the voltage of the capacitor 10 exceeds the time Zener voltage of the Zener diode 13 caused by the time constant of the control circuit, the delay flows to the normal Wet 1 / ",
through the emitter circuit of the transistor 12 an emitter while maintaining the already achieved bias current, the size of which is proportional to the difference 60 parts, this difficulty is solved according to the invention between the voltage of the smoothing capacitor 10 in a simple manner that the control and the Zener voltage is. The size of the emitter circuit 4 (see FIG. 1) also contains an auxiliary control circuit 33 of the current in a large temperature range which, when the magnetron 1 is switched on, is independent of the temperature. The base-emitter decreasing auxiliary excitation current for the voltage of the transistor 12 and the Zener voltage 65, which is designed as a control coil, supplies the magnetic coil 6 of the magnetic temperature coefficients of opposite propellants 1. In the illustrated Atisführungform larity on. is the auxiliary control circuit 33 .lurch through a

To control iles the excitation current of the solenoid 6 with the switch 3 coupled switching contact 34 on

5 6

the output circuit of the rectifier 16, 17 has only a small F ^; nt! adestrom needs to supply, closed capacitor 35 is formed by a through the amplifier 19, 20 to generate the full exciter series resistance 36 via a second pair of inflow through the magnet coil, so that output terminals 37, 38 with the Input circuit of a relatively small capacitor 35 is sufficient transistor amplifier 19 is connected. If the 5 can.

Switch 3 is open, the switch contact 34 is The timing diagram of FIG. 2 shows yet closed the and the capacitor 35 is then up to Magnetrongleichstrom upon closing of the switch 3 of the full supply voltage of the rectifier 16, 17 According to the foregoing, the Magnetronaufgeladen, wherein after DC to b by the curve indicated via the series resistor 36 of the Base electrode of transistor 19 has an auxiliary control curve, the magnetron direct current flowing from a current which, after amplification to the minimum value at switch-on point T _0, gradually rises to the desired value through the magnet coil to transistors 19 and 20. Peak flow «generates maximum excitation current. Then that in the magnetron 1, which, as mentioned above, the magnetic field of the magnetron 1, which shorten from the magne * life of the magnetron, do not occur in the table field of the permanent magnet and the magnetic field ij of the device according to the invention, as the magnetic coil θ is composed, a maxi * here when switching on the magnetron direct current -11 times value. gradually increasing to the desired value, what

If the switch 3 in this device is just a request * in intermittent operation.

Point T _{0 is} closed, the switching contact 34 brings the life of the magnetron with it, opened, whereupon the up to the full output voltage *> A device that has been extensively tested in practice

of the rectifier 16, 17 charged capacitor 35 according to the invention had the following data: discharges through the series resistor 36 and through

the transistors 19, 20 in the magnetic coil 6 a magnetron Delayed decreasing auxiliary excitation current generated. Dimensions of the permanent

its removal rate through the discharge magnets 30 0 20 80 mm, 4 pieces

time constant of the capacitor 35 is conditioned. Magnetic field of the permanent soft constant essentially through the value magnets 30 970 Gauss

of the capacitor 35 and the number of turns in series with it

ended resistance 36 is determined. From the one solenoid 6 1875

switching time T ₀ , the magnetic field of the 3 »dimensions of the magnetic magnetron gradually decreases from a maximum value. ^s P ^ule * 0 80 x 40 mm

so that accordingly the magnetron direct current magnetic field of the magnetic

gradually increases until by the action of the coil 6 at maximum

Control circuit 4 via the control circuit 5 of the magnetron excitation 260 Gauss

direct current reaches the desired stable value 35 overall measurements

Has. ^{of the} magnetron 1 130-80-130 mm

From this point on, the control power of the magnetron takes over 1 2 kW

circle the regulation of the auxiliary control circuit 33rd of the control device furthermore no more influence on the control process transistors 12 19 OC 74

Has. In order to achieve a smooth regulation without decay * o transistor 20 'ASZ 15

To achieve appearances, it is advantageous to use the time resistance 8 '.'. '.'. '.'. '.'. '.'. '.'. 15 ohms

constant of the auxiliary control circuit 33. the through d.e w.derstand 9 680 ohms

Ze.tkonstante of the capacitor 35 and the resistance 10 _Konde nsator 1000 μΡ Standes 36 is determined to be greater than the time constant resistance 11 1500 ohms

of the control circuit 4 to make. In the illustrated * 5 Zener diode 13 OAZ 206

The embodiment is the time constant of the auxiliary capacitor 35 500 uF

Control circuit 33 larger by a factor of 7 than resistor 36 .. '.'. '.'. '.'. '.'. '. 10,000 ohms

of the control loop.

If from this operating position the switch 3 It should be noted here that the protruding c

is opened, the switching contact 34. 50 described control loop closes in a different way;

and the capacitor 35 of the auxiliary control circuit 33 can be formed. The Schaltkontaki 34 can;

charges up to the full output voltage of the DC z. ?. be designed in such a way that at Betätisuni

judges 16 and 17. whereupon when the switch 3 is closed before the switch-on time de

of the switch 3 of the above-described cycle switch contact 34 for charging the capacitor 3i

repeated. It is advantageous here for the auxiliary control 55 to be closed while at the switch-on time <iei

circuit 33 to the input circuit of the DC switch contact 34 as in the execution shown in dtr

Stronger 19. 20 to connect, since the capacitor 35 is opened approximately form.

1 sheet of drawings

Claims (4)

ι J 2 patent claims · the output power of a magnetrong converter, H "in which the changes amount to several 10% 1. Magnetron generator, especially for high-can, is in the supply circuit of the magnetron gene frequency heating, whose magnetron a perma- rators inserted a control circuit of a control loop, has nentmagnetisches magnet system, whose 5 wherein the output circuit of the control circuit to a Anode circuit a switch for the on and magnetic coil of the magnet system of the magnetron Turn off the magnetron and a control is connected and in which the control circuit in circuit contains a control circuit, the output of which the excitation current through the solenoid coil circle in one in the magnet system of the magnetron to stabilize the ·; Magnetron DC controls additionally arranged solenoid a der- io and whereby further for an intermittent operation like excitation current feeds in that when the supply circuit fluctuates, one to switch on and off the contains kings of the anode DC voltage of the magnetron serving switch. trons by changing the on the magnetron from the German patent 738 189 is a acting magnetic field stabilization of the aforementioned magnetron generator with an Anode current is achieved, d a d u r c hg e k e η η- 15 voltages to stabilize the operating point of the draws that the control loop known an additional magnetron. For this purpose the field excitation Lent auxiliary control circuit contains, which when switching on both from the anode voltage and from the of the magnetron is made dependent in the anode charge current by the switch (3) and thereby a Circuit achieved a delayed decreasing auxiliary composite effect. In the known arrangement excitation current in the 20 provided in the magnet system is for this purpose the field effect of the excitation Solenoid supplies. magnets divided into two coils, of which the 2. Magnetron generator according to claim 1, that one is in the anode circuit of the magnetron, characterized in that the auxiliary control circuit passes directly from the anode during the other a voltage source is fed to a DC voltage source. It can also closed capacitor with a discharge resistor protruding a third coil or a permanent magnet is formed, the line being seen as the one of the above voltage source a magnetic field component that is independent of the values with the switch (3) Anodest T.nkreis supplied switching contact, i.e. in the case of the coil with one from the anode, which is independent of the current or the anode voltage when the magnetron is switched on the switch (3) opens. 30 electricity is fed. 3. Magnetron Generalor I claim 2, that the object of the invention is in addition to characterized in that the discharge time condenser of the simple construction of a magnetron is a particularly constant of the capacitor is greater than that of the simple control loop to create the magnetron Control loop. to protect against the inrush current, namely 4. magnetron generator according to claim 1, 2 35 by a corresponding circuit arrangement in or 3, characterized in that the control anode circuit so that the anode current is slow loop of the control loop can be increased by one in the Magne-. tron DC circuit inserted resistor and the task is performed at a magnetron generalor a subsequent low-pass filter is formed, of the type mentioned according to the invention the output circuit being solved via a series resistor 40 in that the control circuit has an additional stood at the base electrode as a comparison auxiliary control circuit, which when switching on the device switched transistor connected magnetrons through the switch in the anode circuit is. whose emitter circuit for this purpose a delayed decreasing auxiliary excitation current in Contains zener diode, the emitter current of which supplies the magnet coil provided in the magnet system. Transistor for exciting the solenoid of the 45. The auxiliary control circuit can be connected to Magnetrons are supplied with a DC voltage source connected to a transistor DC amplifier and the auxiliary control circuit of the regulating capacitor must be formed with an unloading resistor, circle to the input circuit of the transistor DC - whereby the line of the DC voltage source one Current amplifier is connected. coupled to the switch in the anode circuit 5 "switch contact, which is activated when the Magnetrons through the switch opens. Even can be the discharge time constant of the capacitor be larger than that of the control loop. Furthermore can The invention relates to a permanently magnetic magnet and a subsequent low-pass filter be formed by a generator in particular for high-frequency heating, 55 Magnetrongleichstromkreis inserted resistor whose magnetron to a magnetron control circuit of the control circuit, comprising system whose anode circuit a whereby the output circuit via a Series resistance switch for switching the magnetron on and off is connected to the base electrode of a transistor which is connected as a comparator and contains a control circuit of a control circuit, the output circuit of which holds a magnet coil additionally arranged in the magnet system of the emitter circuit for this purpose a Zener diode Emitter current of the transistor feeds an excitation current such that when the magnet coil of the magnetron is excited, fluctuations in the anode DC voltage of the magnet transistor DC amplifier are fed, and d He trons by changing the magnetic field acting on the magnetron an auxiliary control circuit of the control circuit to the input circuit, a stabilization of the connection 65 of the transistor direct current amplifier is connected. odenstrom is achieved. As an advantage of the magnetron according to the invention to reduce the z. B. as a result of Netzspanniings- generator results in an extension of the service life, fluctuations, increasingly occurring changes in the magnetron. Embodiments are in the