BE1026837B1 - Electricity generator - Google Patents

Abstract

Electricity generator comprising a first accumulator of kinetic energy and an auxiliary motor connected by means of a first coupling member to the first accumulator, which auxiliary motor is arranged to be started and coupled to the first accumulator in the event of loss of an electrical network, which generator comprises a second accumulator of kinetic energy connected by means of a second coupling member to said auxiliary motor, which generator comprises a monitoring unit arranged to monitor the supply of energy by the first accumulator and for producing a failure signal upon finding that the first accumulator supplies an amount of energy less than a predetermined threshold, which second coupling member is arranged to couple the second accumulator under control of the failure signal to the auxiliary engine .

Description

Electricity generator

The present invention relates to an electricity generator comprising a first kinetic energy accumulator provided with a first drum mounted on a first transmission shaft, which first accumulator comprises a first electric motor connected to the first transmission shaft and arranged to drive the first drum in rotation when the first motor is supplied with electric current supplied by a power supply network, which generator also comprises an auxiliary motor, in particular a combustion engine, having a first output connected by means of a first member coupling to said first transmission shaft, which generator comprises a drop detector of the electric current supplied by the supply network and which is arranged to detect a drop or loss of said electric current supplied by the network and produce a signal of activation upon detection of such a fall or loss, which auxiliary motor is arranged to be started under control of the activation signal, which first coupling member is arranged to couple the auxiliary motor to the first shaft under control of the activation signal.

Such a generator is generally known, in particular under the name of UPS (Uniterruptable Power Supply). The function of the known generator is to ensure a continuous supply of electrical energy in places such as for example hospitals, airports or bank management centers, where a drop or loss of the electrical current supply supplied by the network could have serious consequences both for the people present and for the electrical installations or data to be processed or saved. The generator comprises a first accumulator, itself coupled to an auxiliary engine which is preferably a combustion engine. The first drum, which is part of the accumulator, usually spins at high speed around its shaft. The first

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-2 accumulator allows kinetic energy to be stored and thus to restore this stored energy during the starting time of the combustion engine. In this way, it is possible to prevent a power cut from causing considerable damage. It is therefore important that the accumulator can deliver kinetic energy as quickly as possible in the event of a drop or loss of current in the power supply network.

A drawback of known electricity generators is that to compensate for a possible failure of the first accumulator, the number of electricity generators is multiplied in such a way that if one of them breaks down there will be at least one other generator. who can take over. Having at least one additional generator makes this solution very expensive. As the failure is most of the time caused by the first accumulator, because the latter is constantly rotating, and not by the auxiliary motor, which is mostly stopped, the use of additional auxiliary motors, which are used very little, is not an economical solution either.

The aim of the invention is to provide an electricity generator capable of coping with a failure of the first accumulator without multiplying the number of generators.

To this end, an electricity generator according to the invention is characterized in that the generator comprises a second accumulator of kinetic energy provided with a second drum mounted on a second transmission shaft, which second accumulator comprises a second electric motor connected to the second transmission shaft and arranged to drive the second drum in rotation when it is supplied with electric current supplied by a power supply network, which auxiliary motor has a second output connected via a second coupling member said second transmission shaft, which generator comprises a monitoring unit arranged to monitor the supply of energy by the

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-3 first accumulator and to produce a failure signal upon finding that the first accumulator supplies an amount of energy below a predetermined threshold, which second coupling member is arranged to couple the second accumulator under control of the failure signal to the engine auxiliary. The use of a second accumulator connected to a second output of the auxiliary motor via a second coupling member, makes it possible to use the same auxiliary motor for the two accumulators, thus saving a additional auxiliary motor while maintaining operational reliability. The use of a first and a second coupling member enables the first and second accumulator to be separately coupled to the auxiliary motor and thus to be used separately. In addition, the use of a failure signal produced when a failure of the first accumulator has been observed, makes it possible to connect the second accumulator in the event of a network failure, and thus ensure continuity in the supply of electricity in the event of a network failure. failure of the first accumulator.

A first embodiment of an electricity generator according to the invention is characterized in that the second electric motor is arranged to be connected under control of the failure signal. Thus the second accumulator is switched on only in the event of failure of the first accumulator. This helps reduce energy consumption.

A second embodiment of an electricity generator according to the invention is characterized in that the first electric motor is arranged to be disconnected under control of the failure signal. The disconnection of the first electric motor allows the disconnection of the first accumulator and thus gives a possibility of repairing the first accumulator.

A third embodiment of an electricity generator according to the invention is characterized in that the first and the second

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-4 drums are supplied and configured to rotate in the same direction of rotation. This guarantees the correct functioning of the generator.

The invention will now be described in more detail with the aid of the drawings which illustrate a preferred embodiment of the generator according to the invention. In the drawings:

Figure 1 illustrates a plurality of power generators connected in parallel according to the prior art;

Figure 2 illustrates a first embodiment of an electricity generator according to the invention; and

Figure 3 illustrates a second embodiment of an electricity generator according to the invention.

In the drawings, the same reference has been assigned to the same element or to a similar element.

In the embodiment according to the prior art and illustrated in Figure 1 there are three generators 2, 3 and 4 which are connected in parallel on a network 1 of power supply. More specifically, these generators are part of a UPS (Uniterruptable Power Supply). Each of the generators has a first accumulator 2-1, 3-1 and 4-1 of kinetic energy, as well as an auxiliary motor 2-2, 3-2 and 4-2. Each of the generators has a first kinetic energy accumulator provided with a first drum mounted on a first transmission shaft (not shown in detail in the drawings). The first accumulator of each generator comprises a first electric motor connected to the first transmission shaft and arranged to drive the first drum in rotation when this first motor is supplied with electric current supplied by the supply network 1. Each auxiliary motor is preferably a combustion engine, having a first output connected via a first coupling member 2-3, 3-3 and 4-3 to said first transmission shaft. Each generator has an electric current drop detector (not shown in detail on the drawings) supplied by the network

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-5 A power supply arranged to detect a drop or a loss of said electric current supplied by the network and to produce an activation signal upon detection of such a drop or loss. Each auxiliary engine is arranged to be started under control of the activation signal. The first coupling member is arranged to couple the auxiliary motor to the first shaft under control of the activation signal.

Generator 4 is an auxiliary generator which is only started when either generator 2 or generator 3 fails or both have failed. The presence of such an auxiliary generator 4 is necessary to overcome such a failure, but remains an expensive solution because the investment is not very profitable.

Figure 2 shows a first embodiment of a set of generators according to the invention. In this embodiment, use is made of two electricity generators, but it goes without saying that the invention is not limited to the use of two generators and that there may be only one generator or more than two generators and this according to the power of the energy to be supplied in the building where the generator (s) are installed. Each electricity generator comprises, as is the case in the prior art, an auxiliary motor 2-2 and 3-2 as well as a first accumulator 2-1 and 3-1 of kinetic energy connected by the first member coupling 2-3 and 3-3.

The generator according to the invention also includes a second 2-1 ’and 3-T kinetic energy accumulator provided with a second drum mounted on a second transmission shaft. The second accumulator comprises a second electric motor connected to the second transmission shaft and arranged to drive the second drum in rotation when it is supplied with electric current supplied by a supply network 1. The auxiliary motor 2-2, respectively 3- 2, comprises a second output connected via a second coupling member 2-3 ', respectively 3-3' to said second transmission shaft. Preferably the first and second motor output

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-6 Auxiliary are located at opposite ends of a rotation axis driven in rotation by the auxiliary motor. This has the advantage of facilitating construction as similar mechanisms can be used at either end of the axis of rotation driven by the auxiliary motor.

The generator also comprises a monitoring unit arranged to monitor the supply of energy by the first accumulator. This is for example carried out by a comparator which receives at a first input the value of the electric current, or a derivative thereof, supplies by the first accumulator and at a second input a threshold value. When the monitoring unit finds that the first accumulator provides less energy than the threshold value, it will produce a failure signal. The second coupling member is connected to the monitoring unit and is arranged to couple the second accumulator under control of the failure signal to the auxiliary engine.

Preferably the second electric motor is arranged to be connected under control of the failure signal. This allows the second motor to be connected only in the event of a failure of the first accumulator, thereby reducing energy consumption. Alternatively the second electric motor can be permanently connected which will allow a faster reaction in the event of failure of the first accumulator. In order to be able to quickly disconnect the first electric motor in the event of a failure, the latter is arranged to be disconnected under control of the failure signal.

The embodiment illustrated in Figure 3 differs from that illustrated in Figure 2 by the presence of a single generator having a first and a second accumulator.

The starting of the two-cell power generator is preferably done by first switching on the first battery 2-1 in Figure 2, and then the second battery. Thus we will couple the first coupling member 2-3 while the second 2BE2018 / 0149

-73 ’will be decoupled. The 2-2 auxiliary engine will be started so that it can run and reach its rated speed, for example from 1500 to 1800 rpm. As the first coupling member is coupled to the auxiliary motor, the latter will then drive the first accumulator which will thus increase in revolutions. The first motor will then function as an electric current generator and will reach a voltage which will be that of the network. When the voltage vector supplied by the first motor corresponds to that of the network, the first accumulator is connected to the network. Then the first coupling member is disconnected. As the first motor turns it will rotate the first drum. The auxiliary engine will then be shut down. Then the second accumulator will be started by following a procedure similar to that described for starting the first accumulator.

The use of the generator according to the invention is done either in a so-called economical mode, or in a very rapid intervention mode. In the economical mode the second accumulator is at rest and only the first accumulator is operational. When a failure occurs on the first accumulator and the monitoring unit finds that the first accumulator is providing an amount of energy less than the predetermined threshold, it will produce the failure signal. The first accumulator will be decoupled from the load it supplies and this under control of the failure signal. It will then be arrested. Under control of the failure signal, the second coupling member will start the second accumulator as described above. Thus the second accumulator can quickly take over from the first and supply the necessary electric current. The auxiliary engine is kept running to drive the second accumulator. Since the first battery, which fails, is shut down, it can be removed from the generator and repaired without causing the generator to stop.

When in the rapid intervention mode the first accumulator is faulty, it is uncoupled and shut down

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-8in the same way as described above. However in this mode the two accumulators rotate and are therefore able to supply current directly. In the event that one of the two fails, it will be decoupled.

Claims (5)

Claims 1. Electricity generator, in particular of the UPS type, comprising a first accumulator (2-1,3-1,4-1) of kinetic energy provided with a first drum mounted on a first transmission shaft, which first accumulator comprises a first electric motor connected to the first transmission shaft and arranged to drive the first drum in rotation when the first motor is supplied with electric current supplied by a supply network (1), which generator also comprises an auxiliary motor (2 -2,3-2,4-2), in particular a combustion engine, having a first output connected via a first coupling member (2-3,3-3,4-3) to said first transmission shaft, which generator comprises a drop detector of the electric current supplied by the power supply network and which is arranged to detect a drop or loss of said electric current supplied by the network and to produce an activation signal when 'a detection of such the fall or loss, which auxiliary motor is arranged to be started under control of the activation signal, which first coupling member is arranged to couple the auxiliary motor to the first shaft under control of the activation signal, characterized in that the generator comprises a second accumulator (2-1 ', 3-T) of kinetic energy provided with a second drum mounted on a second transmission shaft, which second accumulator comprises a second electric motor connected to the second transmission shaft and arranged for drive the second drum in rotation when it is supplied with electric current supplied by a power supply network, which auxiliary motor has a second output connected via a second coupling member (2-3 ', 3- 3 ') to said second transmission shaft, which generator comprises a monitoring unit arranged to monitor the supply of energy by the first accumulator and to produce a signal failure when finding that the first accumulator provides a quantity of energy BE2018 / 0149 - 10 below a predetermined threshold, which second coupling member is arranged to couple the second accumulator under control of the failure signal to the auxiliary engine. 2. Generator according to claim 1, characterized in that the second electric motor is arranged to be connected under control of the failure signal. 3. Generator according to claim 1 or 2, characterized in that the first electric motor is arranged to be disconnected under control of the failure signal. 10 4. Generator according to one of claims 1 to 3, characterized in that the first and the second drum are supplied and configured to rotate in the same direction of rotation. 5. Generator according to one of claims 1 to 4, characterized in that the first and the second output of the auxiliary motor are located at opposite ends of a rotation axis driven in rotation by the auxiliary motor.