BE1026574A1 - Method of supplying an electrical appliance with direct current and accumulator of electrical energy - Google Patents

Abstract

A method of supplying a device with direct current, which comprises converting, in a first stage, an alternating electric current supplied by a distribution network of high-voltage alternating electric current into a medium-voltage alternating electric current and the conversion of the medium voltage alternating electric current into a medium voltage direct electric current, followed in a second stage by the conversion of the medium voltage direct electric current into a low voltage direct electric current, which process also involves in the event of a drop in the network supplying the electrical appliance by an electric energy accumulator, which accumulates electric energy which, in the event of a fall and / or loss of the alternating electric current supply provided by the network, a DC electric current of medium voltage which it supplies at the input of the second st of conversion.

Description

Method of supplying an electrical appliance with direct current and accumulator of electrical energy

The present invention relates to a method of supplying an electrical appliance with direct electrical current, which comprises the conversion in a first stage of an alternating electrical current supplied by a high-voltage alternating electrical current distribution network, in particular a electric current of a voltage greater than 6KV, into an alternating electric current of medium voltage, in particular an electric current of a voltage greater than 350V, and the conversion of alternating electric current of medium voltage into a direct electric current of medium voltage , followed in a second stage by the conversion of the medium-voltage direct electric current into a low-voltage direct electric current, in particular of a voltage less than 50V, which method also involves in the event of a fall and / or loss of the AC power supplied by the Coura distribution network nt alternating electrical supply of the electrical appliance by an electrical energy accumulator.

The present invention also relates to an electric energy accumulator comprising a transmission shaft on which are mounted a first electric motor and a flywheel driven in rotation by this first electric motor to store energy in the flywheel , which accumulator also comprises an auxiliary motor, in particular a combustion engine, connected by means of a coupling member to said shaft, which accumulator comprises a fall and / or current loss detector arranged to detect a fall or a loss of the alternating electric current supplied by the distribution network of alternating electric current and to produce an activation signal upon detection of such a fall or loss, which auxiliary motor is arranged to be started under control of the signal which organ

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-2 coupling is arranged to couple the auxiliary motor to the shaft under control of the activation signal.

Such a method and such an energy accumulator are generally known and they have the function of ensuring a continuous supply of electrical energy, for example in data management plants, where an interruption in the supply of electrical current to computers could have serious consequences, including loss of data. The first electric motor rotates the drive shaft, which in turn drives the flywheel so that the flywheel can accumulate energy. The accumulator thus makes it possible to store energy in the flywheel and to restore this stored energy in the event of a fall and / or loss of the current supplied by the network. In the period of time necessary to start the auxiliary engine, the energy stored in the flywheel will be used to generate electric current and supply the electrical appliances. In this way we can prevent a fall and / or loss of current from causing considerable damage.

In central data management, electronic equipment, especially computers, operate on direct electric current. This therefore requires that the alternating electric current supplied by a distribution network be converted into direct electric current. In addition, as the alternating current supplied by the network is often current of a high voltage, for example from 12KV to 50Hz, this alternating current is converted in a first stage into a direct current of medium voltage, for example of 380V, to distribute it in the building where the management center is located. This direct current will then be converted again in a second stage into a lower voltage, for example 48V, before supplying it to the electronic equipment.

A disadvantage of known energy storage devices is that they produce alternating electric current. The production of this current

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-3alternative, which must be combined with the alternating current supplied by the network, imposes very strict conditions in terms of phases and frequency on the current produced by the accumulator, in order to avoid a disjunction compared to the current supplied by the network. This requires strict control of the speed of rotation of the drive shaft. The current produced by the accumulator is supplied to the input of the converter located at the first stage of the conversion in order to transform the alternating current produced by the accumulator into direct current of medium voltage. This latest conversion results in energy losses.

The object of the invention is to provide a method for supplying an electrical appliance with direct current as well as an electric energy accumulator where the conditions of production of current by the accumulator are less strict than those imposed on the current. where the loss in the conversion to direct current is reduced.

To this end, a method according to the invention is characterized in that the accumulator of electric energy produces, in the event of a fall and / or loss of the supply of alternating electric current supplied by the network, a continuous electric current of average voltage it provides at the input of the second stage of conversion.

An accumulator according to the invention is characterized in that it comprises a generator arranged to produce direct electric current of medium voltage, said accumulator comprising an output connected to an output terminal of the generator.

The production of direct electric current by the generator, which is part of the accumulator, makes it possible to supply this direct current directly at the second stage of the conversion where the direct current of medium voltage is converted into a direct current of low voltage, thus avoiding the loss of energy caused by the conversion of the alternating current produced by the accumulator into direct current. In addition, as it is direct current which is supplied by the accumulator, this current

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-4continuous must not meet strict phase and frequency conditions imposed on alternating current. Tests have shown that the use of the battery according to the invention makes it possible to reduce these losses by at least 15%.

A first preferred embodiment of an energy accumulator according to the invention is characterized in that the generator is mounted on said transmission shaft. This allows the generator to be driven directly by the first accumulator motor and the auxiliary motor.

A second preferred embodiment of an energy accumulator according to the invention is characterized in that the generator is a synchronous generator having a number of poles greater than four and provided with an electric current rectifying diode. This increases the efficiency of the battery and reduces its maintenance.

The invention will now be described in more detail using the drawings which illustrate an embodiment of the battery according to the invention. In the drawings:

Figure 1 shows the typical installation of an energy accumulator;

FIG. 2 illustrates an embodiment of the method according to the invention;

and

FIG. 3 illustrates an embodiment of the accumulator according to the invention.

In the drawings, the same reference has been assigned to the same element or to an analogous element.

FIG. 1 shows the conventional installation of an energy accumulator 7 which serves as an auxiliary source in the event of a fall or loss of electric current supplied by a network 1 of distribution of alternating electric current, in particular an electric current of a tension

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-5 greater than 6KV, more particularly 12KV at 50 Hz. The network is coupled to a transformer 2 which converts the high voltage into a medium voltage of for example 400V and always at 50Hz. An output of the transformer is connected to a coil 3. The accumulator 7, generally called UPS (Uninterruptible Power Supply), is arranged to produce electrical energy in the form of alternating electric current of medium or low voltage. This accumulator comprises a combustion engine used to drive an electric current generator in rotation. The energy produced by the accumulator is coupled via the coil 3 in the supply line 8. The accumulator also includes a flywheel (not shown in Figure 1) to store energy kinetics which will be used to produce electric current during the period of starting the combustion engine.

The function of the accumulator 7 is to provide a continuous supply of electrical energy in places such as, for example, a data management center 6, where an interruption in the supply of electrical current could have serious consequences. As soon as a power cut is noticed, an auxiliary engine, which is part of the accumulator, is started to produce electricity.

In the central data management unit 6 the electronic equipment, in particular the computers, operates with direct electric current. This therefore requires that the alternating electric current supplied by the alternating electric current distribution network must be converted into direct electric current. To this end the alternating current supplied at the output of the coil 3 is converted in a first stage via a first converter 4 into a direct current of medium voltage, for example of 380V, to distribute it in the building. where the management center is located. This direct current will then be converted again in a second stage

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-6 by means of a second converter 5 into a lower voltage before supplying it to the electronic equipment as low-voltage direct current, for example of 48V.

This conversion in two stages applies in the conventional installation of the accumulator also to the energy produced by the accumulator which has the consequence that energy losses occur at the level of this double conversion thus reducing the efficiency of the auxiliary source.

FIG. 2 illustrates an embodiment of the method according to the invention. According to the invention the accumulator 7 comprises a generator 10 (see FIG. 3) arranged to produce direct electric current of medium voltage. The accumulator also includes an output 11 connected to an output terminal of the generator 10. This output 11 is directly connected to the input of the second converter 5. Thus the accumulator directly produces direct electrical current of medium voltage which it provides at the entrance of the second stage of conversion. It is therefore no longer necessary to convert high-voltage alternating current into high-voltage direct current first. Avoiding the first stage of conversion thus reduces energy loss. Tests have shown that the use of the battery according to the invention makes it possible to reduce these losses by at least 15%.

FIG. 3 illustrates an embodiment of the accumulator according to the invention. The accumulator comprises a transmission shaft 12 on which are mounted a first electric motor 13 comprising a first rotor 13-1. The accumulator also includes an exciter 15, comprising a second rotor 15-1, mounted on the transmission shaft, and a first stator 15-2 arranged around the second rotor 15-1. The exciter is connected to the AC distribution network 1. When the first stator 15-2 is supplied with current supplied by the network, it drives the second rotor 15-1 in rotation. As the first 13-1 and the second 15-1 rotor are mounted on the shaft 12, the

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Rotation of the second rotor involves that of the first rotor 13-1. A drum 14 is also mounted by means of bearings on the transmission shaft 12 and envelops the first rotor 13-1. The rotation of the first rotor will cause the drum to rotate, which will then rotate around the shaft and will then function as a flywheel for storing kinetic energy.

The shaft 12 is also connected by means of a coupling member 6 to an auxiliary engine 17, in particular a combustion engine. The accumulator comprises a current loss and / or drop detector (not shown) arranged to detect a drop or loss of the alternating electric current supplied by the alternating electric current distribution network. When such a fall or loss is detected, the detector will produce an activation signal. The auxiliary motor 17 is arranged to be started under control of the activation signal and the coupling member 6 is arranged to couple the auxiliary motor to the drive shaft 12 under control of the activation signal. Thus, in the event of a drop or loss of current supplied by the network, the auxiliary motor will be coupled to the shaft via the coupling member and will thus be able to drive the shaft in rotation.

In order to fill the period between detection of the drop and / or loss of current when the auxiliary motor has reached its speed, the kinetic energy stored in the flywheel 14 will be used to maintain the shaft. transmission in rotation and thus drive in rotation a DC switch 18 which is part of the accumulator 7 and which is also mounted on the shaft.

The accumulator 7, according to the invention, comprises a generator 10 arranged to produce direct electric current of medium voltage. The accumulator includes an output 11 connected to an output terminal of the generator. In the embodiment of Figure 3, the generator comprises a third rotor 19 which is mounted on the transmission shaft 12 and a second stator 20 which extends coaxially

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-8au third rotor 19. This second stator comprises a first set of windings which are galvanically separated from each other. The DC switch 18 is mounted on the driveshaft so as to be juxtaposed to the third rotor 19. The switch 18 is a sectional ring switch provided with a second set of coils which are aligned with the first set of windings forming part of the third rotor 19. The coils of the second series of windings are also galvanically separated from each other.

When the drive shaft 12 is rotated either by the kinetic energy stored in the drum 14 or by the auxiliary motor 17, the switch 18 and the third rotor will also be rotated because they are mounted on the shaft 12.The second stator 20 is supplied with electric current which will thus create a magnetic field. The latter will then be induced in the first set of windings of the third rotor 19 which will have the consequence of inducing an alternating electric current therein. As the first set of coils belong to the third rotor which rotates around the axis the magnetic field the rotation of the third rotor will result in the magnetic field being successively induced in each of the coils of the first set. Thus each of the coils will successively produce an alternating electric current.

As the coils of the first and second set are aligned, the electric current produced in each time a coil of the first set will be induced in the coil of the second set which will face that of the first set where the current is produced. Thus the coils of the second set will each time receive the peak of current produced in the coil of the first set. This succession of current peaks will have the consequence that due to the rotation of the switch, the integral of the current peaks received by the coils of the second

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-9windings will produce a direct electric current which will then be supplied to the output 11. Preferably the generator is a synchronous generator having at least four poles and provided with a rectifier diode of electric current.

The fact that the generator produces direct current directly eliminates the need to very precisely control the speed of rotation of the shaft. Indeed, as it is direct current that is produced, we no longer have to worry about the frequency or the phases of the current produced. This therefore facilitates the production of direct current and makes it more efficient and less expensive.

Claims (5)

Claims 1. A method of supplying an electrical appliance with direct electrical current, which comprises converting, in a first stage, an alternating electrical current supplied by a high-voltage alternating electrical current distribution network, in particular an electrical current d '' a voltage greater than 6KV, into a medium voltage alternating electric current, in particular an electric current of a voltage greater than 350V, and the conversion of the medium voltage alternating electric current into a direct medium voltage electric current, followed in a second stage of the conversion of the medium-voltage direct electric current into a low-voltage direct electric current, in particular of a voltage less than 50V, which method also involves in the event of a fall and / or loss of the power supply alternating electric current supplied by the alternating electric current distribution network al imitation of the electrical apparatus by an accumulator of electrical energy, characterized in that the accumulator of electrical energy produces, in the event of a fall and / or loss of the supply of alternating electrical current supplied by the network , a direct current of medium voltage which it supplies to the input of the second stage of the conversion. 2. Electric energy accumulator comprising a transmission shaft on which are mounted a first electric motor and a flywheel driven in rotation by this first electric motor to store energy in the flywheel, which accumulator comprises also an auxiliary motor, in particular a combustion engine, connected by means of a coupling member to said shaft, which accumulator comprises a fall and / or current loss detector arranged to detect a fall and / or a loss of alternating electric current supplied by the alternating electric current distribution network and to produce an activation signal upon detection of such a fall or loss, which auxiliary motor is BE2018 / 0098 -11 arranged to be started under control of the activation signal, which coupling member is arranged to couple the auxiliary motor to the shaft under control of the activation signal, characterized in that it comprises a generator arranged to produce medium voltage direct current, said accumulator comprising an output connected to an output terminal of the generator. 3. Electric energy accumulator according to claim 2, characterized in that the generator is mounted on said transmission shaft. 4. Electric energy accumulator according to claim 3, characterized in that the generator comprises a rotor mounted on the shaft and a stator which extends coaxially with the rotor, the generator also comprising a direct current switch mounted on the shaft, which switch is a sectional ring switch provided with a first series of windings which are aligned with a second series of windings forming part of the rotor. 5. Electric energy accumulator according to one of claims 2 to 4, characterized in that the generator is a synchronous generator having a number of poles greater than four and provided with an electric current rectifying diode.