FR2916583A1 - "ENERGY CONDITIONER" - Google Patents

Abstract

Electrical assembly comprising a load (3) able to be supplied by an electrical network (2), said electrical assembly comprising an energy conditioner (1) disposed between said electrical network (2) and said load (3), said conditioner ( 1) comprising a battery (E), characterized in that said conditioner (1) comprises a first converter (6), said series converter, adapted to generate an injection voltage for compensating for disturbances of the supply voltage supplied to said load (3) by said electrical network (2), said conditioner (1) having a second converter (7), said parallel converter, adapted to provide a current for compensating current harmonics due to said load (3).

Description

The present invention relates to an electrical assembly comprising a

  energy conditioner, such as uninterrupted power supply. An uninterrupted power supply called UPS (Uninterruptible Power Supply), is a device for protecting electronic equipment, for example a computer, medical equipment, a backup device, a telecommunication device, a device for industrial treatment against hazards electric. A UPS system generally comprises a battery that can be used to power the electronic equipment in the event of an electrical problem on the electrical network. The battery is particularly used in case of micro-power failure (that is to say of electric breakage of a few thousandths of a second), in case of power failure, in case of overvoltage (that is to say when the voltage supplied by the electricity network has a nominal value higher than the maximum value provided for the normal operation of the electronic equipment), in the event of undervoltage (that is to say when the voltage supplied by the electricity network has a nominal value less than the maximum value expected for the normal operation of the electronic equipment) and in the event of voltage peaks (ie instantaneous overvoltages of high amplitude).

  On the other hand, electronic devices are generally non-linear loads that induce current and / or voltage disturbances and are therefore a considerable source of disturbances in the electrical network. Different energy conditioners have been proposed with harmonic compensation and reactive power. However, in these conditioners, the output voltage and the input currents can not be controlled simultaneously.

  The object of the present invention is to propose an electrical assembly comprising a multi-function energy conditioner which simultaneously performs uninterruptible power supply and on-line conditioning with high efficiency. This arrangement makes it possible to compensate for harmonic disturbances in current and voltage, to improve the power factor, to compensate for voltage dips and to effectively adjust the output voltage. For this purpose, the subject of the invention is an electrical assembly comprising a load capable of being supplied by an electrical network, said electrical assembly comprising an energy conditioner disposed between said electrical network and said load, said energy conditioner comprising a DC power source or battery, characterized in that said energy conditioner comprises a first converter, said series converter, adapted to generate an injection voltage for compensating for disturbances of the supply voltage supplied to said load by said electrical network, said energy conditioner comprising a second converter, said parallel converter, adapted to provide a current for compensating current harmonics due to said load.

  The second converter can also compensate for the power factor. The goal is that the network current obtained after compensation is sinusoidal and in phase with the mains voltage. Preferably, said first converter comprises two switches and a first filter formed by an inductor and a capacitor.

  Preferably, said second converter comprises two switches and a second filter formed by an inductor.

  Preferably, the first switch, respectively the second switch, of the first converter, and the first switch, respectively the second switch, of the second converter being connected by a bus, a set of two mid-point capacitors being connected to said bus, the capacitor the filter of the first converter being connected to the electrical network, said capacitor of the filter of the first converter and said load are connected to a point of the same potential as the midpoint of the two capacitors. According to one embodiment of the invention, in normal operating mode: as long as the supply voltage supplied by said electrical network has a value within a predetermined tolerance range, the output voltage of said first converter is substantially zero the voltage across said load being substantially equal to the supply voltage supplied by said power grid, and, in the presence of disturbances of the supply voltage supplied by said power grid, said first converter provides a voltage of injection for compensating for said disturbances. According to one embodiment of the invention, in normal operating mode, said second converter: provides a current for compensating current harmonics due to said load. - ensures the charging of said battery from the power supplied by said power grid. Preferably, in emergency operating mode, that is to say in case of interruption of power supply by said power grid: said first converter supplies the load with all the power required from the power supply. battery, said second converter is inactive The invention will be better understood, and other objects, details, features and advantages thereof will appear more clearly in the following detailed explanatory description, of several embodiments of the invention. invention given by way of purely illustrative and non-limiting examples, with reference to the attached schematic drawings.

  In these drawings: FIG. 1 is a general block diagram of an energy conditioner; Figure 2 is an electrical schematic diagram of a second electrical assembly including a power conditioner according to an embodiment of the invention; and FIG. 3 is a block diagram of the control means of the parallel converter of the conditioner of FIG. 1 or FIG. 2. Referring to FIG. 1, there is shown an electrical assembly comprising a conditioner 1 disposed between a electrical network 2 and a load to be protected 3. The electrical network 2 is capable of supplying the load 3. The conditioner 1 comprises an AC supply line 4, a DC supply line 5, an input terminal BE and a output terminal Bs. The conditioner 1 comprises a battery E, a first converter 6, 25 said series converter, and a second converter 7, said parallel converter. A transformer 8 is arranged between the input terminal BE and the series converter 6. The primary of the injection transformer 8 is connected in series between the electrical network 2 and the load 3. The secondary is connected to the output of the serial converter 6. A filter 9 is placed at the input of the conditioner between the electrical network 2 and the terminal BE to limit the harmonic disturbances of high-frequency voltage. Similarly, a filter is placed between the second converter and the output terminal Bs to limit the high frequency components of current from the parallel converter. Figure 2 shows a second electrical installation. The elements of the assembly identical to the first electrical assembly are designated by the same reference numeral and are not described again. Here, the electrical assembly does not include a transformer. The series converter 6 comprises two switches TI and T2 and a filter formed by an inductance Ls and a capacitor Cs. The output of the filter is connected in series with the load 3 and the network 2. The parallel converter 7 comprises two switches T3 and T4 and a filter formed by an inductance Lf. The output of the filter is connected to the load 3. Note that the first converter 6 is called the series converter 20 because the voltage V; oad across the load 3 is equal to the sum of the voltage supplied by the converter 6 and The second converter 7 is called the parallel converter because it is connected in parallel with the load 3. The operation of the conditioner 1 will now be described starting from a normal operating mode in which the switch SW1 is closed, that is to say that the electrical network 2 is able to supply the load 3.

  In this mode of operation, as long as the voltage Vnet supplied by the electrical network 2 has a value within a predetermined tolerance range, the output voltage of the series converter 6 is substantially zero and the voltage Vload across the terminals of the load 3 is substantially equal to the voltage Vnet. The parallel converter 7 supplies a current IF, through the inductance Lf, to cancel the harmonics of the current at the coupling point P between the line AC 4 and the load 3. In addition, the parallel converter 7 ensures the charging of the battery E from the power supplied by the electrical network 2. In the presence of disturbances of the voltage Vnet, for example voltage dips, oscillations and / or harmonic disturbances, the series converter 6 supplies a voltage making it possible to compensate the disturbances of the voltage Vnet.

  It will be noted that only a small portion of the power supply, corresponding to the disturbances of the voltage Vnet, is provided by the battery E via the series converter 6, the major part of the supply power coming directly from the network 2. achieves a high efficiency compared to conventional uninterruptible power supply. In case of interruption of the voltage supply by the network 2, control means (not shown) control the opening of the switch SW1 to separate the electrical network 2 and the load 3. The control means control simultaneously the closing of the switch SW2. In this mode of operation, called backup, the serial converter 6 acts as a DC / AC converter and provides the load 3 all the power required from the battery E. In the emergency operating mode, the parallel converter 7 is inactive. The method of controlling the conditioner 1 will now be described in more detail.

  The fundamental component of the charging current iL is determined using a phase locked loop (not shown). FIG. 3 shows a block diagram of the control means 10 of the parallel converter 7. The control means 10 comprise means 11 for determining the harmonics intended to receive as input the instantaneous value of the current iL and to output the value instantaneous of the corresponding iharm harmonic current. The control means 10 comprise means 12 for detecting the disturbances of the voltage Vnet intended to receive as input the value of the voltage Vnet and to output, on the one hand the value of a disturbance voltage Vpert, and on the other hand a sin () indicator synchronized with the fundamental voltage of the network. A subtractor 13 makes it possible to subtract from current iharm a current io proportional to the indicator sin () to obtain a reference current iref.

  A subtractor 14 makes it possible to subtract the current du of the current iref, the result obtained being transmitted to a current controller 15. The controller 15 controls the switches 16 of the parallel converter, connected to the battery E, which generates the current IF passing through the inductance Lf. The gains of the current controller 15 are determined for example by the root locus method. The control means (not shown) of the serial converter 6 use the synchronized sinusoidal signal produced by the phase-locked loop as the reference voltage to supply the load 3. In the emergency operating mode the sinusoidal signal is generated to maintain the continuity the Vload charge voltage. In normal operating mode, the reference voltage is transmitted to the phase locked loop and the voltage injected by the series converter 6 is set by a PID (Proportional Integral Derivative) controller with a good frequency response and a wide bandaged. Preferably, the converters 6 and 7 have a bandwidth sufficient for them to be able to inject the harmonics up to the 23rd without significant phase shift. Conditioner 1 combines the advantages of an online UPS system with a line-interactive UPS system. Conditioner 1 has good transient characteristics, good stability, good output voltage, even when load 3 is highly nonlinear, higher efficiency than conventional in-line UPS, very good reduction capability voltage and current harmonics and an input power factor close to unity. As shown in FIG. 2, the first switch T1 of the first converter 6 and the first switch T3 of the second converter 7 are connected by a first conductor wire 17. Similarly, the second switch T2 of the first converter 6 and the second switch T4 of the first second converter 7 are connected by a second conductor wire 18. These two conductors son 17,18 form a so-called continuous bus because of the connection to this DC energy source bus such as the battery E. In addition, it is provided a set of two capacitors Cdc1, Cdc2 midpoint, which is connected to the DC bus 17,18, that is to say that this set of two capacitor Cdcl, Cdc2 is connected firstly to the first lead 17 and secondly to the second conductor wire 18. The middle point means that the two capacitors Cdc 1 and Cdc2 are connected to the same point, in the manner of a voltage divider.

  The capacitor Cs of the filter of the first converter 6 is connected to the electrical network 2. The capacitor Cs of the filter of the first converter 6 and the load 3 are also connected to a point of the same potential as the midpoint of the two capacitors Cdci, Cdc2 • Il As a result of such an assembly it is not necessary to use a transformer to be able to inject a voltage in series with the electrical network. In addition, thanks to such a conditioner shown in Figure 2, the first converter 6 and the second converter 7 each require only two switches T1, T2 and T3, T4. Thus, the absence of transformer and the reduced number of switches 15 reduces the size, weight and price of the conditioner 1 compared to a conventional UPS online system. For short-duration voltage dips, it is also possible to dispense with the battery E, thus modifying the control method of the second converter 7.

Although the invention has been described in connection with several particular embodiments, it is quite obvious that it is in no way limited thereto and that it comprises all the technical equivalents of the means described as well as their combinations if these These are within the scope of the invention.

Claims (7)

  1. Electrical assembly comprising a load (3) able to be supplied by an electrical network (2), said electrical assembly comprising an energy conditioner (1) disposed between said electrical network (2) and said load (3), said conditioner (1) comprising a DC power source or battery (E), characterized in that said energy conditioner (1) comprises a first converter (6), said series converter, capable of generating an injection voltage ( Vini) making it possible to compensate for disturbances in the supply voltage (Vnet) supplied to said load (3) by said electrical network (2), said conditioner (1) comprising a second converter (7), said parallel converter, suitable for supplying a current (if) for compensating the current harmonics due to said load (3).   2. Electrical assembly according to claim 1, characterized in that said first converter (6) comprises two switches (T1 and T2) and a first filter formed by an inductor (Lb) and a capacitor (Ce).   3. Electrical assembly according to one of claims 1 or 2, characterized in that said second converter (7) comprises two switches (T3 and T4) and a second filter formed by an inductor (Lf). 10   4. Electrical assembly according to any one of claims 1 to 3, characterized in that, the first switch (T1), respectively the second switch (T2), the first converter (6), and the first switch (T3), respectively the second switch (T4), the second converter (7) being connected by a bus (17,18), a set of two capacitors (Cdcl, Cdc2) with a midpoint being connected to said bus (17,18), the capacitor (Cg) of the filter of the first converter (6) being connected to the electrical network (2), said capacitor (Cs) of the filter of the first converter (6) and said load (3) are connected to a point of the same potential as the point middle of the two capacitors (Cdci, Cdc2) •   Electric circuit arrangement according to one of Claims 1 to 4, characterized in that, in the normal operating mode: as long as the supply voltage (Vnet) supplied by the said electrical network (2) has a value included in a predetermined tolerance range, the voltage (V; ni) output of said first converter (6) is substantially zero, the voltage (Vload) across said load (3) being substantially equal to the supply voltage (Vnet) provided by said power grid (2), and, in the presence of disturbances of the supply voltage (Vnet) supplied by said power grid (2), said first converter (6) provides an injection voltage (V; to compensate for said disturbances.   6. Electrical assembly according to claim 5, characterized in that, in normal operating mode, said second converter (7): -provides a current (if) for canceling harmonics of the current flowing through said load (3), - ensures charging said battery (E) from the power provided by said power grid (2). Electrical assembly according to claim 5 or 6, characterized in that, in emergency operating mode, that is to say in the event of interruption of the supply by said electrical network (2): said first converter ( 6) provides the load (3) with all the power required from the battery (E), said. second converter (7) is inactive.