FR2680297A1 - Supply device for a nonlinear load - Google Patents

Abstract

A power supply device connected to an a.c. network and including a rectifier (5), a high-voltage transformer (8) with a secondary winding (19) connected to the load (1), a high-frequency switching element (14) connected to a control circuit (16), and a measuring device (28) for measuring current intensity in the primary circuit of the transformer. Said measuring device (28) comprises a sensor (30) combined with a device (34) for recording a voltage which is proportional to the intensity flowing through the element (14), and averaged over a high-frequency oscillation period, devices (43, 38, 41) for processing values such as the output value of device (34), the rectified mains voltage value ¦u¦, and a set power value P0, as well as an error amplifier (46), the output signal of which controls circuit (16). The resulting switching frequency control provides both a variation in mains current intensity which is proportional to the mains voltage supply, and power consumption which is equal to said set power value P0. The device is useful for supplying, power to a microwave oven magnetron.

Description

Device for feeding a non-linear load
The invention relates to a device for supplying a non-linear load which is connected to an alternating current distribution network. The supply device comprises a rectifier connected to the terminals of said network and formed by a full-wave diode bridge, the output of which is connected by two supply lines to the primary winding of a high voltage transformer, the secondary winding being connected by two supply lines to the non-linear load, a high frequency interference suppression filter positioned at the output of said rectifier and consisting of a choke and a capacitor, a high frequency switching element positioned on one supply lines and having a trigger connected to a control circuit and a device for measuring the intensity of the current flowing in the supply line containing the switching element.

Said intensity measurement device makes it possible to detect a value of current flowing in the supply line containing said switching element. The value thus detected is sent to the control circuit which applies trigger signals to the trigger of the switching element. The trigger signals sent to the control circuit make the switching element conductive by authorizing the passage of current from the other supply line connected to the primary winding to the supply line containing the switching element.

The average intensity delivered at each pulse being a function of the switch control frequency, said control frequency can be controlled by the measured value of said average intensity so that the latter remains constant.

Current measurement devices for controlling the switching element have been developed, but these devices are generally complex, expensive and do not take into account the laws of variation of the sine current. Consequently, the current consumed by the device is not sinusoidal and the power applied to the load is sensitive to the heating of the components and to variations in the mains voltage.

The object of the invention is to remedy these drawbacks by implementing an intensity measurement device correcting the frequency of the triggering signals of the control circuit.

According to the invention, the measuring device comprises a sensor intended to take the intensity on the supply line and associated with a storage device which makes it possible to store a voltage proportional to the intensity passing through the switching element averaged over a period of the high frequency oscillation, a device for squaring the rectified mains voltage | u | entering it on the supply and averaging line of the value obtained over the period of the sector, a first multiplier performing the product of said last average value by the value of the voltage stored by the storage device, a second multiplier performing the product of rectified mains voltage | u | him by the setpoint power P0, and an error amplifier whose inputs are connected to the outputs of the multipliers and whose output signal controls the control circuit of the switching element so that the frequency control The resulting switching mechanism ensures both a variation in the intensity drawn from the sector proportional to the voltage delivered by said sector, and a power consumption equal to the setpoint power P0.

Thanks to the device according to the invention, the intensity of the current in the supply line is measured at each opening of the switching element, this calculation making it possible to take into account all the variations in the average intensity of the pulses. In this way, the frequency of the trigger signal is corrected either increasing or decreasing, thereby acting on the power supplied to the non-linear load. The power absorbed by the load can therefore be adjusted at each switching and, therefore, the absorbed intensity can be kept close to a sinusoidal shape and said absorbed power controlled by a set value.

The characteristics and advantages of the invention will become apparent from the description which follows, by way of nonlimiting example, with reference to the accompanying drawings in which
Figure 1 shows an example of mounting a
intensity measurement device according to the invention and
positioned in a supply circuit of a
magnetron; Figure 2 shows a circuit of a
device for measuring the intensity of a charge not
linear adapted to be mounted in the circuit of the
figure 1.

According to FIG. 1, the circuit is intended more particularly for supplying a non-linear load such as a magnetron 1 of a microwave oven from an alternative distribution network arriving at terminals 3 and 4 of the circuit. These terminals 3 and 4 are connected to a rectifier 5 which is formed by a full-wave diode bridge and the output of which is connected to two lines 6 and 7 supplying a high voltage transformer 8. A high interference filter frequency is positioned at the output of said rectifier 5 and consists of a self-inductance 9 and a capacitor 10. The lines 6 and 7 are connected respectively to the ends 11 and 12 of the primary winding 13 of the transformer 8. The supply line 7 also includes a switching element 14 having a trigger 15 connected to a control circuit 16 as well as a switching aid device 16 '. Said switching element 14 is constituted by a unidirectional current switch. The unidirectional switch 14 is connected, for example, in series with a diode 20 preventing reverse current to the source, thus ensuring a better ratio: average current injected on effective current in the primary circuit. In other embodiments not shown, the diode 20 can be mounted in parallel with the unidirectional switch 14. The circuit also includes a capacitor 18 connected in parallel to said winding 13, as well as a choke 17 connected in series with the assembly thus formed by the capacitor 18 and the primary winding 13. The inductor 17 is coupled to a secondary winding 21 whose ends are connected to the heating element 20 of the magnetron 1.

The secondary winding 19 of said transformer 8 respectively has two terminals 21 and 22 respectively connected to two supply lines 23 and 24 connected one 23 to the cathode 2 of magnetron 1 and the other 24, to the anode 25 of said magnetron which is also connected to earth 26. The frequency of the trigger signals varies according to the value of the current flowing in the supply line 7.

The value of said current is analyzed by an intensity measurement device 28. The measurement device 28 comprises a sensor 30 intended to take the intensity from the supply line 7 and associated with a storage device 34 which makes it possible to memorize a voltage proportional to the intensity passing through the switching element 14 averaged over a period of the high frequency oscillation, a device 43 for squaring the rectified mains voltage | u | entering it on the supply line 6 and averaging the value obtained over the period of the sector, a first multiplier 38 performing the product of said last average value by the value of the voltage stored by the storage device 34, a second multiplier 41 effecting the product of the rectified mains voltage | u | him by the power of reference PO, and an error amplifier 46 whose inputs 45-49 are connected to the outputs S1, S2 of the multipliers 41-38 and whose output signal controls the control circuit 16 of the element of switching 14 so that the enslavement of the resulting switching frequency ensures both a variation of the intensity drawn from the sector proportional to the voltage delivered by said sector, and a power consumption equal to the set power PO.

As shown diagrammatically in FIGS. 1 and 2, the sensor 30 comprises a winding, for example, that of a high frequency intensity transformer 29. The winding 30 has two terminals 31 and 32, one of which 32 is connected to ground. A resistor R1 is connected in parallel to the winding 30 at the terminals 31 and 32. The terminal 31 is connected to one of the inputs 33 of the storage device 34 constituted, for example, by a sample-and-hold amplifier controlled by the activation of 'a clk clock has on an input 35.

The activation of the clock clk has control of a switching device (not shown) which is an integral part of the amplifier 34 which triggers the measurement of the value of the intensity of the supply line 7 by its storage at an instant called d 'sampling. This selected sampling instant corresponds to the instant when the switch 14 is open and the current in lines 6 and 7 is zero, the voltage stored at said instant then being equal to the average value of the current in the switch 14 with the time constant of the high frequency intensity transformer 29.

In another embodiment, shown diagrammatically in broken lines in FIG. 1, the sensor 30 is constituted by a winding 31 carried out on the magnetic circuit of the self-inductance 17 charged by an integrator resistance circuit
R and capacitor C.

According to yet another embodiment not shown, and in which also the inductor 17 is mounted in series with the switching device 14, the sensor 30 is constituted by a high-pass filter associated with an RC integrator circuit connected directly to the terminals of the self inductance 17.

According to FIG. 1, the measuring device 28 is connected by a line 28A to the supply line 6, for example, upstream of the capacitor 18 connected in parallel with the primary winding 13, and this line 28A takes the mains voltage straightened | u | which is sent (see FIG. 2), on the one hand, to an input 40 of the second multiplier 41 and, on the other hand, to an input 42, of the device 43 for squaring the absolute value of the voltage of the recovered sector. While the output 36 of the amplifier 34 is connected, to an input 37 of the first multiplier 38.

The second input 44 of the multiplier 41 receives the reference power Po of the non-linear load at start-up, this value being corrected during operation. The output S1 of said multiplier 41 is connected to a first input 45 of the error amplifier 46. The output 47 of the square elevation device 43 is connected to an input 48 of the first multiplier 38.

The output S2 of said multiplier 38 is connected to a second input 49 of the error amplifier 46. The output 50 of the error amplifier 46 is connected to an input 51 of the control circuit 16.

With reference to FIG. 2, the intensity measurement device according to the invention operates in the manner described below. The sample-and-hold amplifier 34 thus makes it possible to store the value of the current flowing on the supply line 7.

The amplifier 34 delivers, at a determined instant, the corresponding value I to a multiplier 38 which makes it possible to carry out the product of said intensity by the absolute value of the square of the rectified mains voltage | u | taken from the output 47 of the device 43. The product P1 is therefore P1 = <IUI2> .I. and its value is delivered on the output S2 of the multiplier 38 connected to the output 49 of the error amplifier 46.

The multiplier 41 performs the product of the absolute value of the rectified mains voltage | u | taken from the supply line 6 by the setpoint power P0 of the load and delivers, on its output S1, the product P2 = | u | . P0. This product P2 is sent to the input 42 of the error amplifier 46. The amplifier 46 compares the input signals 42 and 49, that is to say if in equilibrium condition we have (u)
P0 = <(u) 2> .I ..

The output signal 50 from said error amplifier 46 is sent to the input 51 of the control circuit 16 which controls the switching element 14, so that the enslavement of the resulting switching frequency ensures both a variation of the intensity taken from the sector proportional to the voltage delivered by said sector and a power consumption equal to the set power P0.

Claims (7)

Claims 1. Device for supplying a non-linear load connected to an alternating current distribution network and comprising a rectifier (5) connected to the terminals (3 and 4) of said network and the output of which is connected, by two lines of supply (6 and 7), to the primary winding (13) of a high-voltage transformer (8), the secondary winding (19) being connected by two supply lines (23 and 24) to the load not -linear (1), a high frequency switching element (14) positioned on the supply line (7) and having a trigger (15) connected to a control circuit (16), and a measuring device (28) the intensity of the current flowing in the supply line (7) characterized in that, the measuring device (28) comprises a sensor (30) intended to take the intensity on the supply line (7) and associated with a storage device (34) which stores a voltage proportional to the current intensity sant the switching element (14) averaged over a period of the high frequency oscillation, a device (43) for squaring the rectified mains voltage entered on the supply line (6) and averaging of the value obtained over the period of the sector, a first multiplier (38) performing the product of said last average value by the value of the voltage stored by the storage device (34), a second multiplier (41) performing the product of mains voltage rectified by the setpoint power PO, and an error amplifier (46) whose inputs (45-49) are connected to the outputs (S1, S2) of the multipliers (38-41) and whose output signal controls the control circuit (16) of the switching element (14) in such a way that the enslavement of the resulting switching frequency ensures at the same time a variation of the intensity drawn from the sector proportional to the voltage delivered by said sector, and a power consumption equal to the power setpoint PO. 2. Supply device according to claim 1, characterized in that, the sensor (30) taking the intensity in the supply line (7) is a high frequency intensity transformer (29). 3. Supply device according to claim 2, characterized in that, the storage device is a sample-and-hold amplifier connected to the terminals of the transformer (29) and whose chosen sampling instant corresponds to the instant or l 'switch (14) is open and where the current in the lines (6 and 7) is zero, the voltage stored at said instant then being equal to the average value of the current in the switch (14) with the time constant of the transformer high frequency intensity (29). 4. Power supply device according to claim 3, characterized in that, the blocking sampler amplifier (34) has an output (36) connected to an input (37) of the first multiplier (38) which is itself connected by an input (48) to the square elevation and averaging device (43) and one output (52) of which is connected to one (49) of the inputs of the error amplifier (46), the other (45 ) of the inputs of said error amplifier being connected to the output of the second multiplier (41), one input (44) of which receives the setpoint power PO and another input (40) of which is connected to the supply line (6) , itself at the input (42) of the device (43). 5. Supply device according to claim 1 and further comprising a choke (17) mounted in series with the switching device (14), characterized in that the sensor (30) is constituted by a winding (31) made on the magnetic circuit of the inductor (17) charged by an integrator circuit (32). 6. Supply device according to claim 1 and further comprising a choke (17) connected in series with the switching device (14), characterized in that the sensor (30) is constituted by an associated high-pass filter to an integrator circuit connected to the terminals of the inductor (17). 7. Supply device according to any one of the preceding claims, characterized in that the non-linear charge is a magnetron.