FR2648639A1 - Two-voltage power supply device - Google Patents

Abstract

Power supply device of the type comprising main rectifying means D20, D21, D22, D23 connected at the input A11, A12 to terminals receiving an alternating voltage and delivering at output A13, A14 a first rectified voltage characterised in that it furthermore comprises a full-wave auxiliary rectifier module D25, D26, D27, D28 with two inputs A15, A16 and two outputs A17, A18, each of the two inputs of which is connected respectively, by a capacitor C20, C21, to the terminals A11, A12 receiving the alternating voltage, and one of the outputs A18 of which is connected to one of the outputs A14 of the main rectifying means, so that the auxiliary rectifier module delivers a second rectified voltage having a polarity common with the first rectified voltage.

Description

 The present invention relates to the field of electrical supply devices capable of delivering two continuous rectified voltages of different values and having a common polarity, from a single alternating voltage.

 The power supply device according to the present invention can give rise to numerous applications; it can be used for example for the supply of discharge lamps or in the context of switching power supplies.

 Many power supply devices delivering two continuous rectified voltages from a single alternating voltage and having a common polarity have already been proposed.

 These known devices can be grouped into three categories illustrated schematically in Figures I to 3 attached. In these figures, reference has been AI1, Al2, the input terminals of the circuit receiving the alternating voltage, MB of the modules supplied with low voltage and MH of the modules supplied with high voltage.

 FIG. 1 shows a first category of known dual-voltage electrical supply devices. According to this first category, the high voltage modules MH are connected to the terminals 711, A12 by a diode Dl ensuring a single-wave rectification. Likewise, the low-voltage modules MB are supplied via a diode D2 ensuring single-phase rectification. The branch comprising in series the diode D2 and the module (s) MB is itself connected to the input terminals Ail, A12, by means of a ballast capacitor C1. A D3 dicde is provided in parallel with the D2-MB branch to cyclically discharge the capacitor C1.

 The conventional device illustrated in FIG. I has the major drawback of delivering little power due to the monoalternation rectification.

FIG. 2 shows a second category of known dual-voltage electrical supply devices. The known device shown in FIG. 2 appended comprises a bridge of 4 diodes D4, D5, DS, D7 arranged in full-wave rectification, the inputs of which are connected to the terminals All, A12. If necessary, a filtering capacitor C2 can be connected in parallel with the output of the rectifying bridge D4 to
D7. The high voltage MH modules are connected to the output of the rectifier bridge. The device also includes tension-reducing means. The LV modules are connected in series with an RI resistor, at the output of the rectifier bridge D4, D5, D6, D7. A Zener ZI diode and a capacitor
C3 are connected in parallel with low voltage MB modules.

 The devices of the type represented in FIG. 2 have the major drawback of causing significant heating of the resistance R1.

 FIG. 3 shows a third category of known dual-voltage electrical supply devices. More precisely, according to this third category, the continuous rectified high voltage is obtained using conventional means not shown. The low voltage is obtained using a transformer T and a full-wave rectifier bridge DS, D9, D1G, Dol 1. The primary Tl of the transformer is connected to the terminals All, A12. The secondary T2 of the transformer is connected to the input of the rectifier bridge D8 to DII. The low voltage MB modules are connected to the output of the rectifier bridge. The devices of the type shown in FIG. 3 have the drawback of requiring a transformer T which is generally expensive, heavy and bulky.

 The object of the present invention is to propose a new dual-voltage electrical supply device which is simpler, more reliable and inexpensive.

 This object is achieved according to the present invention by means of an electrical supply device of the type comprising main rectification means connected at the input to terminals receiving an alternating voltage and delivering at output a first rectified voltage characterized in that it comprises in addition an auxiliary full-wave rectifier module with two inputs and two outputs, each of the two inputs of which is connected respectively, by a capacitor, to the terminals receiving the alternating voltage, and one of the outputs of which is connected to one of the outputs main rectifying means, so that the auxiliary rectifier module delivers a second rectified voltage having a common polarity with the first rectified voltage.

 According to a preferred characteristic of the present invention, the main rectification means comprise a bridge of four diodes arranged in full-wave rectification.

 The auxiliary rectifier module can be the subject of different variant embodiments.

 According to a first variant, the device according to the present invention is designed to deliver, from a single alternating voltage, a high voltage equal to the peak voltage of the alternating voltage, and a low voltage, for example delivering two rectified voltages DC 300 volts and 12 volts respectively from an alternating voltage of 220 volts. In the context of this first variant, the auxiliary rectifier module is essentially formed by a bridge of four diodes arranged in a Graëtz point, two of these diodes having an electrode of the same type connected to the common polarity output of the means main turnaround.

 According to a second variant, the device in accordance with the present invention is designed to deliver, from a single alternating voltage, a high voltage equal to the peak value of the alternating voltage, and a very high voltage, for example delivering two voltages continuous rectifiers of 300 volts and 1500 volts respectively from a single alternating voltage of 225 volts. In the context of this second variant, the auxiliary rectifier module comprises four diodes arranged in a Graëtz bridge, two of these diodes having an electroce of the same type connected to the output having the common polarity of the main rectifying means and two of these diodes being by elsewhere connected to the aforementioned capacitors by means of voltage multipliers.

 These voltage multiplier means are advantageously formed by capacitors and diodes arranged in Greinacher mounting.

 Other characteristics, objects and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings given by way of nonlimiting examples and in which - Figures I to 3 previously described represent the state of the art, and - Figures 4 and 5 show two embodiments of the supply device according to the present invention.

We see in Figure 4 attached the power terminals
All, Al2 receiving an alternating voltage, for example of 220 volts rms.

 A bridge of 4 diodes D20, D21, D22, D23, arranged in double-wave rectification in Graëtz bridge, is connected to the supply terminals All, Al2. This bridge D20 to D23 delivers a rectified high voltage at its outputs Al3, A14 and constitutes the aforementioned main rectification means.

 The high voltage modules MH are therefore connected to the output terminals A13, A14 of the bridge D20 to D23.

 More specifically, the diodes D2, and D22 have their cathodes connected to the positive output terminal A13 while their anodes are connected respectively to the input terminals Al2 and Ail.

 Likewise, the diodes D21 and D23 have their anodes connected to the negative output terminal A14, while their cathodes are connected respectively to the input terminals Al2 and All.

 The device according to the present invention shown in FIG. 4 further comprises an auxiliary full-wave rectifier bridge formed by four diodes D24, D25, D26 and D27 arranged in Graètz bridge. The inputs of the auxiliary rectifier bridge D24 to D27 are referenced AIS, A16. The outputs of the auxiliary rectifier bridge are referenced A17, A18. Said second rectified voltage is available between these outputs A17, AIS. The AIS input of the auxiliary bridge is connected to the AC voltage terminal A12 via a capacitor C2r.

Symmetrically, the input A16 of the auxiliary bridge is connected to the AC voltage terminal AI1 by means of a capacitor C21. Preferably the capacitors C20 and C21 have identical capacities. Diodes D24 and D26 have their cathodes connected to the positive output terminal
A17 while their anodes are connected respectively to the input terminals A15 and A16. Symmetrically, the diodes D25 and D27 have their anodes connected to the negative sortle terminal A18 while their cathodes are connected respectively to the input terminals AIS and A16.

 Preferably a capacitor C22 is connected to the output terminals A17 "A18 to filter the low voltage available on the output of the auxiliary bridge. In addition, preferably, a Zener diode Z20 is connected to the output terminals A1, A18, in order to limit the low voltage available.

 As shown schematically in Figure 4 the low voltage modules' 1B can thus be connected directly to the output terminals Al7, AIS. of the auxiliary bridge.

It will be noted that according to a very important characteristic of the present invention, the negative output terminal A18 of the auxiliary bridge is connected to the negative output terminal A14 of the main rectification means. Thus MB low voltage modules and high voltage modules
HT have a common mass.

 If necessary, the potential common to the two rectified voltages can be defined not by connecting the two outputs A14 and AIS, but by connecting the outputs A13 and A17.

 Preferably, a filtering capacitor is also provided between the output terminals A13, A14, of the main rectifying means. This capacitor has not been shown in the appended figures to simplify the illustration.

During the alternation during which the voltage on the input terminal A12 is positive with respect to the voltage on the input terminal Hall, the current passing through the charges MH passes through the diodes D20 and D23. During the same alternation, the capacitor C20 charges while the capacitor C21 discharges and the current passing through the charges
MB goes through diode D24 and through diode D27, for an instant corresponding to the discharge of capacitor C21, then through the diode
D23. The latter prohibits charging in the opposite direction of the capacitor
C21.

During the following alternation, during which the voltage on the terminal All is positive relative to the voltage on the terminal A12, the current passing through the charges Mil passes through the diodes D22 and D21. During the same alternation, the capacitor C21 charges and the capacitor C20 discharges, and the current passing through the charges MB passes through the diode D26 and through the diode D25, during an instantaneous instant corresponding to the discharge of the capacitor C2û, then by the diode
D21. The latter prohibits charging in the opposite direction of capacitor C25.

 It will be noted that the capacitors C25 and C21 serve to limit the current in the rectifying means to: liaire and the charges MB but do not in any case risk heating.

The capacitance C of the capacitors C20 and C21 is determined to obtain sufficient power to supply the loads MB on the basis of the relationship
CV'f = UI, relation in which C represents the rapacity of the capacitors and V represents the peak charge voltage of the capacitors (peak voltage of the alternating voltage minus the voltage drop in the diodes and the stabilized voltage across the terminals of the Zener diode Z20), f represents the frequency of the alternating supply voltage, U represents the stabilized voltage across the terminals of the Zener diode Z25 and I represents the desired current in the loads MB.

 We will now describe the second embodiment according to the present invention illustrated in Figure 5 attached.

 This FIG. 5 shows the main rectifying means formed by a bridge of 4 diodes D20, D2l, D22 and D23 arranged in Graëtz bridge, which receives on its inputs All, A12 an alternating voltage and delivers between its outputs A13, Al4 a first rectified voltage capable of supplying MH modules.

 Also found in Figure 5 auxiliary recovery means whose inputs are referenced A1S, A16 and the outputs are referenced A17, AIS.

 The input terminals A15, A16 of the auxiliary rectifier module are connected to the input terminals A12, AI l. via capacitors C20, C21.

 The auxiliary rectifier module comprises a bridge of four diodes D24, D25, D26, D27 arranged as a full-wave rectifier bridge.

However, according to FIG. 5, the auxiliary rectifier module further comprises voltage multiplier means connecting the diodes D26 and D2 to the inputs .4! 5, A16. Thus the second rectified voltage available between the outputs A17, AIS is a very high voltage capable of supplying NlTH modules.

The aforementioned voltage multiplier means are formed of capacitors and diodes arranged in a manner known per se in mounting
Greinacher.

 More precisely, the diodes D25, D27 have their anodes connected to the output A18, while their cathodes are connected respectively to the inputs AIS, A16.

Diode D26 has its cathode connected to output A17 while its anode is connected to the Greinacher assembly formed by diodes D261, D262,
D263, D264 and capacitors C265, C266, C267 and C268 (the four diodes D261, D262, D263 and D264 are in series between A16 and D26, their cathodes being directed towards D26; C265 connects AiS and the cathode of D261;
C266 connects the anode of D262 and the cathode of D263; C267 connects the anode of
D261 and the cathode of D262; C268 connects the anode of D263 and the cathode of
D264).

Diode D24 has its cathode connected to output A17 while its anode is connected to the Greinacher assembly formed by diodes D241, D242,
D243, D244 and capacitors C245, C246, C247 and C248 (the four diodes D241, D242, D243 and D 244 are in series between AIS and D24, their cathodes being directed towards D24; C245 connects A16 and the cathode of D241
C246 connects the anode of D242 and the cathode of D243; C247 connects the anode of
D241 and the cahode of D 242; C248 connects the anode of D243 and the cathode of
D244).

 If the AC input voltage between All, A12 is 22G volts rms, the rectified voltage between A17, A18 is 150ru volts.

 The output A18 is connected to the output A14 to define a potential common to the two rectified voltages.

If necessary, the potential common to the two rectified tensons can be defined not by connecting the two outputs Ala and AIS, but by connecting the outputs A13 and A17. In this case, it is possible to place the Greinacher type voltage multipliers in series with the diodes
D25, D27 and not in series of the diodes D2a, D26. However, this change is not imperative.

 Of course the present invention is not limited to the particular embodiment which has just been described but extends to all variants in accordance with its spirit.

Claims (10)

 1. Electrical supply device of the type comprising main rectifying means (D20, D21, D22, D23) connected at the input (AIl, A12) to terminals receiving an alternating voltage and delivering at the output (A13, A14) a first rectified voltage characterized by the fact that it further comprises an auxiliary rectifier module (D25, D26, D27, D28) full wave alternation with two inputs (A15, A16) and two outputs (A17, AIS), each of the two inputs of which is connected respectively, by a capacitor (C20, C21), to the terminals (All, A12) receiving the alternating voltage , and one of the outputs (AIS) of which is connected to one of the outputs (A14) of the main rectification means, so that the auxiliary rectifier module delivers a second rectified voltage having a common polarity with the first rectified voltage.  2. Power supply device according to claim i, characterized in that the main rectifying means comprise a bridge of four diodes (D20, D21, D22, D23) arranged in full-wave rectification.  3. Power supply device according to one of claims I or 2, characterized in that the auxiliary rectifier module is essentially formed by a bridge of four diodes (D24, D'5, D26, D27) arranged in Graètz bridge, two of these diodes (D25, D26) having an electrode of the same type connected to the common polarity output (A14) of the main rectifying means.  4. Power supply device according to one of claims I or 2, characterized in that the auxiliary rectifier module comprises four diodes (D24, D25, D26, D27) arranged in Graètz bridge, two of these diodes (D25 , D27) having an electrode of the same type connected to the common polarity output (Ai4) of the main rectifying means and two of these diodes (D24, D26) being moreover connected to the abovementioned capacitors by means of multiplier means voltage (D261-D264, C265-C268 ,; D24l-D244, C25-C2 = S).  5. Power supply device according to claim 4, characterized in that the voltage multiplier means are advantageously formed of capacitors and diodes arranged in assembly Greinacher.  6. Power supply device according to one of claims I to 5, characterized in that the two capacitors (C2O, C21) connecting the inputs (AIS, A16) of the auxiliary full-wave rectifier bridge to the terminals (All, A12 ) receiving the AC voltage, are identical.  7. Power supply device according to one of claims I to 3, characterized in that a filtering capacitor (C 22) is connected between the output terminals (A17, A18) of the auxiliary full-wave rectifier bridge.  8. Power supply device according to one of claims I to 3 and 7, characterized in that a Zener diode (zoo) is connected between the output terminals (Ai7, A18) of the auxiliary bridge (D24, D25 , D26, D27).  9. Power supply device according to one of claims I to 8, characterized in that a filtering capacitor is connected between the output terminals (A13, Alla) of the main rectifying means.  10. Power supply device according to one of claims 1 to 9, characterized in that connecting means directly connect the anodes of two diodes (D21, D23) of the main rectifying means to the anodes of two diodes (D25 , D27) of the auxiliary module.