RU2318283C2 - Power supply system for off-line electric mains - Google Patents

Abstract

FIELD: power supply systems for off-line electric mains such as those of oil boring platforms or ships.

SUBSTANCE: proposed power supply system has at least one generator 3 and at least two three-phase systems 1a, 1b, 1c; generator 3 has at least two three-phase sets of windings and two three-phase current systems 1a, 1b shifted in phase and fully or partially dispensing with converter transformers; sets of generator 3 windings are spatially disposed in them in compliance with electric phase shift of three-phase systems 1a, 1b. Both three-phase current systems 1a, 1b form together primary system 1 and supply with power secondary three-phase current system 3 by means of transformer unit 4.

EFFECT: reduced mass and size.

6 cl, 4 dwg

Description

The invention relates to a power supply system for autonomous power networks, and the power supply system contains at least one generator and at least two three-phase current systems.

By a power supply system for autonomous power grids it is necessary to understand a complex power system, namely, a power system in which electric energy is generated, transmitted and finally converted into other forms of energy, moreover, the system is spatially limited in size and is not comparable with the national power supply system. Such systems can, in particular, be found in marine and / or mobile installations. For example, on ships and other marine vehicles, drilling platforms or other isolated, preferably associated with the sea technical facilities with energy demand.

Power supply systems corresponding to the generic concept often contain at least two three-phase current systems that are electrically biased in phase and which, through parallel converters, supply electric drives. Due to the phase shift of three-phase current systems, the higher harmonics of current and voltage are reduced. Currently, such phase-shifted three-phase current systems are obtained using converter transformers, and the phase shift of three-phase current systems is caused by the corresponding switching groups.

In the case of the previously described energy supply systems for autonomous electric networks and, in particular, at sea, the high weight of the applied system components is an aggravating problem. Therefore, there are currently various approaches for solutions that try to optimize devices belonging to the system, such as converter transformers and converters with respect to their weight.

The objective of the invention is to further improve the power supply system for autonomous networks, which contains at least one generator and at least two three-phase current systems, in particular, with respect to the problem statement described above.

According to the invention, this is achieved due to the fact that the generator of the power supply system contains at least two three-phase winding systems that are associated with three-phase current systems, moreover, voltage is induced in the winding systems and the generator winding systems are spatially arranged so that the voltage of both systems three-phase current, respectively, are electrically offset in phase relative to each other.

Due to the fact that according to the invention in order to obtain both three-phase current systems, converter transformers are completely or at least predominantly rejected, a significant advantage is achieved with respect to weight and costs and space is also saved.

Preferably, the electrical phase shift between the three-phase current systems is 30 °. This phase shift is particularly advantageous with respect to reducing the higher harmonics of the current and voltage in connected, under certain circumstances, supplied energy by means of parallel converters of the subsequent three-phase current system.

Preferably, the generator winding systems are arranged in the grooves so that a minimum short circuit current is set. Thus, the undesired supply of energy through inductive coupling on the stator side of the winding systems in the generator is noticeably reduced.

It is advisable that the load be associated with more than one of the three-phase current systems. Just in the presence of more than two or, correspondingly, multiple of two three-phase current systems in this way, loss of redundancy in the system can be avoided.

Preferably, the power supply system comprises at least one primary system and at least one secondary three-phase current system, wherein at least two three-phase current systems form a primary system that is associated with at least one of the secondary systems three-phase current. Thus, in the primary and secondary systems can be used various devices for switching and / or conversion, which are designed for different voltage ranges. The calculation of the voltage ranges in this case is preferably determined by the load supplied. In general, this results in a cost advantage, since under certain circumstances more advantageous devices for lower voltage ranges can be used.

Preferably, the secondary three-phase current system is connected to a generator. Thus, it is achieved that the loads on the secondary or primary system must be supplied with energy also when problems arise in the production of energy in another system.

Advantageously, the connection between the at least one primary system and the at least one secondary three-phase current system is such that the energy generated by the generator connected to the secondary three-phase current system can be supplied to the primary system. Thus, in emergency cases, the generator connected to the secondary system can also supply power to the loads connected to the primary system.

Examples of implementation and further advantages of the invention are explained on the basis of the attached drawings. Moreover, the figures show:

Figure 1 is an exemplary diagram of a power supply system according to the invention for autonomous power networks;

Figure 2 is an exemplary diagram of a power supply system according to the invention with loads on the primary system;

Figure 3 is an example for a transformer device for communication of a primary and secondary system;

Figure 4 is an example for a transformer device for communication of a primary and secondary system.

Figure 1 shows an exemplary diagram of a power supply system according to the invention for autonomous power networks. In this case, the generator 3, which is connected to both three-phase current systems 1a, 1b, generates energy, for example, by burning diesel fuel. The generator 3 in this case contains two three-phase winding systems, which are associated with the three-phase current systems 1a or 1b, respectively, and in the winding systems the voltages are induced and the winding systems inside the generator 3 are spatially arranged so that the voltages of both three-phase current systems 1a, 1b electrically phase shifted relative to each other. In this way, converter transformers can be completely or at least to a predominant degree to create both three-phase current systems.

Both three-phase current systems 1a, 1b together form the primary system 1. Preferably, the three-phase current systems 1a, 1b are electrically phase-shifted by 30 ° relative to each other and, through at least one transformer device 4, energize the secondary three-phase current system 2. Thus In this way, the higher harmonics of current and voltage in the secondary system 2 are reduced. In the embodiment shown in FIG. 1, the transformer device 4 contains two transformers connected in parallel.

Both the primary system 1 and the secondary system 2 can be connected loads not shown in the drawing, for example, motors or other drive devices. Associated with the secondary system 2, the generator 7 can serve as an emergency generator and provide power in both the secondary system 2 and the primary system 1 in case the main generator 3 does not work.

Figure 2 shows another exemplary diagram of a power supply system according to the invention, with loads 6a, 6b connected to the primary system 1. Generator 3 is connected to both three-phase current systems 1a, 1b, which are preferably electrically phase-shifted by 30 ° relative to each other. Both three-phase current systems 1a, 1b form the primary system 1. Through both static converters 5a, 5b, motors 6a, 6b are energized.

The primary system 1 is connected to the secondary three-phase current system 2 by means of two transformers 4. The figure does not show other loads that can be connected to the primary system 1 in addition to the motors 6a, 6b. With the secondary three-phase current system 2 through the terminals 8a, 8b, 8c, other loads, not shown in more detail in the drawing, and at least one generator, not shown in more detail, are connected.

In the example embodiment according to FIG. 2, due to the design of the generator 3, it is ensured that when using loads suitable for drilling in oil wells, as motors 6a, 6b on the side of the stator windings connected to the three-phase current systems 1a, 1b, uniform load distribution is ensured. Moreover, in the primary system 1, it is advisable to operate at the highest possible voltage level.

The connection of the secondary three-phase current system 2 with the primary system 1 occurs through transformers 4 in a symmetrical manner. For example, both transformers 4 have on the primary side a connection according to the triangle pattern, on the secondary side, however, a connection according to the triangle pattern or, accordingly, a star.

Figure 3 and Figure 4 show further embodiments of the transformer device 4 for coupling the primary system 1 with the secondary three-phase current system 2. The individual winding systems of the transformer device 4 are then aligned with both primary three-phase current systems 1a, 1b or, respectively, the secondary three-phase current system 2 with contact terminals 8a, 8b, 8c. The transformer devices 4 shown in FIGS. 3 and 4 can be implemented as an integrated transformer device, that is, they contain on the secondary side for each of the terminals 8a, 8b, 8c, as shown schematically in the drawings, only one winding system.

In the case of the transformer device shown in FIG. 3, the winding systems are located on the side of the secondary three-phase current system 2 according to the star pattern.

In the case of the transformer device shown in FIG. 4, the winding systems are located on the side of the secondary three-phase current system 2 according to the triangle diagram.

Figure 1 and Figure 2 show the corresponding elementary power supply systems for stand-alone power networks. At least two such energy supply systems can communicate with each other. It is also possible to link at least one power supply system according to the invention with existing power supply systems for an autonomous power supply network.

An energy supply system, which consists of several elementary energy supply systems, such as those shown in FIG. 1 or FIG. 2, for covering a correspondingly higher energy demand can also be made in such a way that, in addition to the main generator 3, the following main generators 3. The energy supply system can also be designed in such a way that it contains several primary systems 1 that supply energy to one or more secondary systems 2. The energy supply system abzheniya may also be designed so that one primary system 1 energises one or several secondary phase current systems 2 and / or one secondary a three-phase current system 2 is powered by one or more primary systems 1.

The energy supply system according to the invention is generally cheaper with at least the same power, flexibility and capacity remaining and has significantly less weight than existing systems, and requires, in addition, due to savings otherwise necessary to create two shifted phase of three-phase current systems 1a, 1b of current converters is much less space than existing systems.

Claims (6)

1. The power supply system for autonomous power grids, which contains at least one generator (3) and at least two three-phase current systems (1a, 1b), characterized in that the generator (3) contains at least two three-phase winding systems, which are aligned with three-phase current systems (1a, 1b), moreover, voltage is induced in the winding systems and the generator winding systems (3) are spatially arranged so that the voltages of both three-phase current systems (1a, 1b) are electrically displaced along phase relative to each other a friend, while the power supply system contains at least one primary system (1) and at least one secondary three-phase current system (2), and at least two three-phase current systems (1a, 1b) form the primary system (1), which is associated with at least one of the secondary three-phase current systems (2), and loads are associated with the primary system (1). 2. The power supply system according to claim 1, characterized in that the electrical phase shift between the three-phase current systems (1a, 1b) is 30 °. 3. The power supply system according to claim 1 or 2, characterized in that the winding system of the generator (3) is placed in the grooves of the generator (3) so that the minimum short circuit current is set. 4. The power supply system according to claim 3, characterized in that the load (6a, 6b) is connected to more than one of the three-phase current systems (1a, 1b). 5. The power supply system according to claim 4, characterized in that the secondary three-phase current system (2) is connected to the generator. 6. The power supply system according to claim 5, characterized in that the connection between at least one primary system (1) and at least one secondary three-phase current system (2) is made in such a way that the energy generated by the generator associated with the secondary three-phase current system (2) can be connected to the primary system (1).

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