CS215415B1 - Wiring for adjusting the load characteristics of a high frequency generator for induction or dielectric heating - Google Patents

Abstract

The invention relates to the field of high-frequency generators and addresses the adjustment of the load characteristic of high-frequency generators. A circuit for adjusting the load characteristic of a high-frequency generator, in which between a tube connected to an oscillating circuit and an anode source with a limiting anode voltage Vamax. and with a limiting anode current Iamax., containing a high-voltage transformer, a rectifier and a regulator Va, a divider connected to the voltage Va is inserted, according to the invention a second resistor is inserted between the tube and the divider and a pair of oppositely connected diodes is inserted between the divider and the anode source, of which the first diode is connected by its outer pole to the terminal of the divider and the second diode is connected by its outer pole to the terminal of the second resistor and the inner poles of the pair of oppositely connected diodes are connected via the central terminal to the anode source regulator, while the signal from the first resistor of the divider and the signal from the second resistor have the same magnitude when the ratio of the anode voltage Va to the anode voltage Ia is equal to the ratio of the maximum values of the voltage and current Vamax. : Iamax. High-frequency generators with a circuit for adjusting the load characteristic according to the invention are intended primarily for induction or dielectric heating

Description

The subject of the invention is a circuit for adjusting the load characteristics of a high-frequency generator for induction or dielectric heating.

Currently, high frequency generators are used for various induction or dielectric heating applications. Each application represents a load on the generator, the size of which varies greatly from one case to another. For example, in the induction heating of a metal non-magnetic object whose shape assumes a free-coupled inductor, the generator is under-loaded and provides low power. Conversely, when a steel object is heated to a temperature below the Cujonium point, inserted into a tightly coupled inductor, the generator is often overloaded so that operation is prevented. The same is true for dielectric heating. Generator load is understood to be a load resistor R _e , which replaces the resonance oscillating circuit connected to the generator tube. The delivered power P depends on the load according to the relation P = U ² / Re, where Ua is the high frequency i voltage at the anode. This dependence is expressed by the load characteristic U ² = f (P), indicated in Fig. 1. The anode supply voltage is constant and is maintained by a regulator connected to the anode generator supply. The controller is controlled by a signal drawn from a resistor which is part of a voltage divider connected to the anode voltage Va. The load resistance R _e = U ² a / P is given by the tangent of the angle α, which for any working point A forms a line that passes through this point and the origin of coordinates, with the horizontal axis (P). The load changes appear by changing the angle α, thereby shifting the operating point A along the characteristic curve. Thus, not only the power P, but also the anode current I _and the electron withdrawal are changed. If the load increases, ie changes! šuje If the load resistance R _E, and thus the angle a in Fig. 1, current _I increases to the permitted limit value _and I max. Loading above this limit can not be allowed if it has been compromised or anode tube source. Překroěí If the current limit _and I, the traffic is interrupted overcurrent protection. Therefore, the usable part of the characteristic ends at point B, whereby the anode current I _and reaches * I _and max. If this current I _and max is not exceeded, the oscillating circuit must be arranged so that the load resistance R _e is always higher than certain minimum value R _e min. Then, however, in applications which also little burden on the generator and which can define a specific loading resistance R max _e., The corresponding small power P - see Fig. 1. The operating point is here moved to position C. The size of the load resistor R _e is dependent on properties of the heated object and on the inductor coupling factor. The load resistance can be increased or decreased by selecting capacitance or inductance, or by changing the coupling between the primary and secondary transformer windings. The power P can be controlled by selecting a different voltage V _a . The load characteristic of FIG. 1 is thereby shifted. The disadvantage of such a circuit is that the power P is too low for applications that represent a high load resistance R _e max. See Fig. 1, working point C15415. The components of the oscillating circuit must be selected so that even for applications that represent a minimum load resistance R _e min., anode current I _a does not exceed limit l _and max. see working point B, fig. 1. R _e max. ratio: R _e min. it is given in advance, it corresponds to the extent to which the various applications under consideration may differ from one another.

The above-mentioned disadvantages of the known solutions are largely eliminated by the circuit according to the invention for adjusting the load characteristics of a high-frequency generator for induction or dielectric heating, the principle being that a second resistor is inserted between the tube and the divider. diodes connected to each other, the first diode connected to the divider terminal by an external pole and the second diode connected to the second resistor terminal by an external pole, and the internal poles of the pair of diodes connected to each other are connected via an intermediate terminal to the anode source controller. at the ratio of the anode voltage V _and the anode voltage I _and , equal to the ratio of the maximum values of voltage and current V _and max: I _and max, the dividers and the second resistance signal have the same magnitude. Another object of the invention is that an absolute value converter is connected between the second resistor and the pair of opposed diodes, the input side of which is connected to the output terminal of the second resistor and the output side is connected to the terminal of one external pole of the pair of opposed diodes. on the output side transducer of the absolute value of the reverse polarity to that at the input side and a ratio of the anode voltage _and the anode current I _a equals the ratio of the maximum values of voltage and current V _and max.: I _and max. is the same size as the signal voltage _V dividers.

The main advantage of the circuitry according to the invention is that it extends the range of applicability of high-frequency generators for various induction or dielectric heating applications. The improved load characteristic of the circuit according to the invention is evident from FIG. 2. The characteristic has a branch C-B valid for constant voltage V _a , similar to [characteristic of FIG. the characteristic continues with the second branch B — D valid for constant current I _a . This is accomplished by the anode source controller J by changing the anode voltage V _y . When load changes occur; in branch C — B it changes the anode current I _and at constant voltage V _a . In branch B — D the voltage V _and at! constant current I _and . Current I _a can be selected _and close to the value I max. power (P) can be as required according to the invention regulate J simultaneously selecting another voltage _and in branch B, and C by selecting another current _{I, and} in branch B-D. The characteristic of FIG. 3 thus shifts all at the same time over the entire C-D range. ¹ It follows that the extent of the respective change in load resistance R _e min. up to R _e max. is greater than the known characteristic of FIG. 1. According to the invention, the operating point may occur between points C-D, whereas in the original characteristic of FIG.

only between points C — B. On the other hand, if the ratio of resistances R _e max: R _e min, which corresponded to the differences between the individual applications according to FIG. higher loads between working points E — D. This gives ϊ an increase in P power for low-load applications that previously corresponded to the duty point

C, while according to the invention there will be in these applications; and power corresponds to point E. Anode current I _and returns to the anode from the cathode source and the oscillating tube, which depending on the connection of the generator 'is not or is electrically connected to the earth ground of the entire device. However, the input signal for the anode source controller is always connected to a grounded ground via one pole. For these reasons, the invention is described in two variations, from which the first or the second is used, depending on the type and connection of the generator.

An example of a circuit according to the invention for adjusting the load characteristics of a high-frequency generator for induction or dielectric heating is shown in the accompanying drawings, in which: FIG.

Fig. 2 is a load characteristic of the present invention; Fig. 3 is a first example of the present invention suitable for a generator whose cathode J of the tube is not 4 is a second example of a circuit according to the invention, suitable for a generator whose electrode cathode is directly galvanically connected to a grounded frame.

The circuit for adjusting the characteristics of the high-frequency generator is according to the invention such that the inductor 2 (Fig. 3), in which the heated object 1 is located, is connected to the secondary winding 3 of the output transformer whose primary winding 4 together with the capacitor battery 5 form an oscillating circuit . This oscillating circuit behaves at the resonance with respect to the electron 6 as an imagined load resistance R _e . The tube 6 is supplied from the anode source 7 and its grid is excited from the excitation transformer 8. The anode source 7 supplies to the tube 6 the supply voltage V _a and the anode current I _a . The DC and AC circuits are separated from each other by a choke 9 and a barrier capacitor 10. The anode source 7 has a high voltage transformer, a rectifier and a regulator that maintains a constant voltage V _and by means of a signal drawn from resistor 11 which is part of a divider 12 _a . Tubes between the cathode 6 and the divider 12 is inserted between the second resistance divider 12 is the 14th sensor giving a signal proportional to the anode voltage V _{and the} second resistor 14 is a sensor giving a signal proportional to the anode current I _a. Between the divider 12 and the anode source 7 is a pair of opposing diodes 17, 18, of which the first diode 17 is connected via an external pole to the terminal 13 of the divider 12 and the second diode 18 is connected via an external pole to the terminal 16 of the second resistor 14;

the poles of opposite pairs of connected diodes 17,18, are connected via a central terminal 19 connected to the controller 7 of the anode source, the signal of the first resistor 11 and the signal divider 12 of the second resistor 14 have the same size if the ratio of the anode voltage V _and current I to the anode _and is equal to the ratio of the maximum values of voltage and current V _and max.: I _and max. In Fig. 4, where another example of wiring according to the invention is shown, the oscillating circuit and excitation transformer which can be made according to Fig. 3 are not shown. In this example of the circuit according to the invention, a transmission is interposed between the second resistor 14 and the pair of diodes 17, 18 connected to each other. the absolute side of which the input side is connected to the output terminal 21 of the second resistor 14 and the output side is connected to the terminal 22 of one external pole of a pair of diodes 17, 18 connected to each other. than at the input side and at the ratio of the anode voltage V _and the anode current I _and equal to the ratio of the maximum values of the voltage i and the current V _and max: I _and max is equal to the voltage signal V _{and the} divider 12.

The function of the circuit according to the invention is as follows: If the signal of the output terminal 16 prevails over the signal from the terminal 13 of the divider 12 and the output terminal 16, which occurs at a higher generator load, i.e. lower load resistance R _e , the signal proportional to the anode current I _and through the second diode 18, while the signal proportional to the voltage V _a from the terminal 13 of the divider 12 is obstructed by the first diode 17. relief where current _I is relatively small, the anode source to the controller 7 is supplied from the signal terminals 13 of the divider 12, is proportional to voltage _V, through the first diode seventeenth signal proportional to the current _{I, and} is also obstructed by means of a second diode controller controls 18th anode source 17 such that the received signal has a constant magnitude (selectable), thereby adjusting generator power as needed. An example where the cathode of the generator tube 6 is galvanically directly coupled to a grounded frame of the device is shown in Figure 4, where | is not shown again oscillating circuit 4, and the excitation transformer 8. These parts involved can be similarly performed as in Fig. 3. the tube 6 is fed from the anode of the anode voltage source 7. the source 7 _and is supplied to divider 12 from which on terminal 13 is branched signal proportional to voltage V _a. anode current I _and generates the second resistor 14 a signal proportional to this current output terminal and finished 21st Both the divider 12 and the second resistor 14 are connected to each other at a grounded connection terminal 15. A signal proportional to the current I _and input from the output terminal 21 to; converter 20 to an absolute value, which converts it to a signal with reverse polarity, the projecting terminal 22. This video signal is also proportional to the current I _a. The terminal 13 of the divider 12 and the terminal 22 of the transducer 20 to an absolute value are bridged by a pair of diodes 17 and 18, the central terminal 19 and the grounded connection terminal 15 of both sensors, i.

the divider 12 and the second resistor 14 supply the control signal to the anode source controller 7. The divider 12, the second resistor 14 and the transducer 20 to an absolute value 1 are selected such that the signal between the divider terminal 13 and the connecting terminal 15 is the same the terminal 22 of the converter 20 to the absolute value and from the connection terminal 15 in the case that the anode source 7 gives the voltage V _and max and the tube 6

Claims (2)

A circuit for adjusting the load characteristics of a high-frequency inductive or dielectric heating generator, wherein between an electron connected to an oscillating circuit and an anode source, being an anode voltage limit V _and max and an anode current limit I _and max containing a high voltage transformer; rectifier and voltage regulator _and is interposed divider connected to the voltage V _a, characterized in that between the tube (6) and the divider (12) is inserted between the second resistor (14) and the divider (12) and an anode source (7 ) a pair of opposing diodes (17, 18) is inserted, of which the first diode (17) I is connected to the divider terminal (13) by an external pole 2 above draws current _I max. Operation of the controller of the anode source 7 is the same as in the example of FIG. 3. The converter 20 to an absolute value means known electronic converter to absolute value, but which may be replaced by a circuit according to the invention the transducer or other ferrodynamickým . INVENTION ^! (12) and the second diode (18) is connected via an external pole to the terminal (16) of the second resistor (14) and the internal poles of the pair of diodes (17, 18) connected to each other are connected via an intermediate terminal (19) to the anode source controller (7). ). Connection according to claim 1, characterized in that an absolute value converter (20) is connected between the second resistor (14) and the pair of diodes (17, 18) connected to each other, the input side of which is connected to the output terminal (21). a second resistor (14) and an output side is connected to a terminal (22) of one outer pole of a pair of diodes (17, 18) connected to each other.