SE515953C2 - High voltage DC insulated electric power plant - Google Patents

Abstract

An electric power plant comprising a driven ac machine (1) connected to an ac-dc converter (2) and a pair of electrically conductive shells (3, 4) arranged as an inner (3) and an outer (4) shell, substantially concentrically surrounding each other, the ac machine and the ac-dc converter being surrounded by the inner shell.

Description

35. Q oo oo o 515953 STATE OF THE ART, THE PROBLEMS The electric power plants that have been described under technical area, ie electric power plants that are part of a DC series link and where the electric power plants include a driven AC machine and at least one AC-DC inverter and associated plant parts, will in terms of insulation technology, an AC voltage generated in the powered AC machine is generated at a low or medium voltage level and - due to the connection of the AC machine and the AC-DC converter to the electric power system, high voltage DC potential relative to earth.

Documentation on how the problems with high DC potential stress on series-connected DC power plants can be solved is very limited, probably due to the fact that such power plants / power plants have not been proven to be or have been in operation.

Technically, a solution is given in US 4057736, "Electrical power generation and distribution system". First, a summary of the embodiments described in the US publication will be given. Due to the fact that the reported embodiments involve system technical problems that have not been taken into account in the US document, a relatively detailed description of these problems related to the reported embodiments follows.

US 4057736 states that “a plurality of relatively low voltage generating stations are connected in series to cumulatively produce the high voltage needed for long distance transmission line delivery. Power-generating devices of successive stations are supported on insulative structures of progressively greater height ..... .. The generating devices may take various forms including, for example DC generators ... or AC-generators connected to 20 25 30. . n r on n 5.15 _9535 converters (fig 4) driven through insulative drive shafts Power may be converted to smaller voltages at the distribution region by coupling a plurality of electrical motors in series, each being supported on insulative structure ”. It is clear from the rest of the text that the high-voltage “long distance transmission line” can be a single conductor and that earth is used as a return conductor. Thus, primarily according to Figures 1 and 16 of U.S. Pat. is increasingly DC-stressed relative to earth and the ground return. Thus, both one end of the generating stations connected in series and one end of the consumers connected in series are directly connected to ground. In order to cope with the DC insulation technical problems, according to the US document, machines and converters are supported by some form of insulator dimensioned for ever higher DC potential stress, "insulative structures of progressively greater height", and that the shafts of both generators and consuming motors have an insulating intermediate to ground. It is further apparent from Figures 9 and 15 of the U.S. Pat. Figure 9 also shows that more than two single conductors can be used, for example in connection with internal parallel connection of generating stations.

However, as indicated above, there are not insignificant problems associated with the embodiments described in the above.

US script. Some of these problems will be reported on the following lines. With the reported embodiments, it becomes difficult to maintain the total power of the electric power plants in the event of earth faults in the DC loop and / or insulation faults inside the series-connected electric power plants, - limit fault currents to values that are harmless to the electric power system / power plants in the event of earth faults in the DC loop and / or insulation faults inside the series-connected electric power plants, - achieve a simple and safe bypass of a power plant in the event of a fault or during service - master the electric fields around electrical and / or passive plant parts such as machines, converters etc. to harmless values - use established bodies for computerized control, regulation, protection, communication, etc.

It can also be stated that the US document does not include any control strategy either during normal operation or in various fault conditions.

Consequences of the mentioned problem areas must be briefly reported. It is very important to be able to maintain the generated transmission power of the electric power plants even in the event of a fault in the electric power plants and / or on the incoming transmission lines. If a ground or insulation fault occurs, according to the US document, there are no reported embodiments or measures to keep the fault currents that occur to harmless values. Bypassing of a faulty "generating station" is only reported when the "station" consists of four generating parts and then in a very complicated way (according to figure 13) with the help of logic circuits and electromagnetic electrical switches. It is also the case that if a “station”, for example driven by a renewable energy source, is not allowed to deliver the generated power to the DC loop, incoming turbines and 20 25 30 35 .v00 ua. 515 953 The rotating parts of the AC machine to accelerate within a few seconds to such rotational speeds that their mechanical strength limit will be exceeded by difficult mechanical and electrical. damage as a result. Measures to prevent this are also not reported. An electric power system with mixed series ~ and parallel-connected "stations" also means that it can be difficult to determine where an error has occurred.

With regard to the distribution of the electric fields around all potential electrical and / or passive plant parts, ie machines, converters, etc., it is the case that these are not determined solely by their constructive design. The field distribution depends to a large extent on how earthed objects temporarily or continuously, in the form of assembly or otherwise, approach the said plant parts or are in the vicinity of the plant parts. This means that the distribution and concentration of the electric field can change significantly in the event of an unintentional approach to earthed parts, for example in connection with accidents, during service, rebuilding and other things.

This means that great demands must be placed on the surrounding touch protection. In addition, field concentrations can lead to major problems with partial discharges.

SE 9904740-9, "Electric power systems based on renewable energy sources" describes a series-connected DC electric power system that belongs to the same technical area as the present invention, ie an electric power system where input AC machines and AC ~ DC converters are exposed to high DC potential. The application states an embodiment with an AC-DC inverter for power supply of DC power to an AC power network without describing the system order. In SE 9904740-9 and in SE 9904753-2, “Use of HVDC-insulated conductors in magnetic current carriers”, an embodiment is stated with regard to the AC machines that master the high DC potential that occurs in these systems. It appears from these publications that cables with extruded insulation with high DC potential resistance have recently emerged, described, among other things, in “Extruded 10 20 25 30 35 oo oo oo. 515 953 DC-power cables and accessories for use in HVDC transmission systems ”, published in ICC Fall Meeting 1999, pp 1 - 7, authored by P. Carstensen, K. Johannesson and A. Gustafsson. By using such cables and conductors with an inner and an outer semiconductor layer, possibly with so-called MIN D cables, ie a cable with thick-surface oil impregnated paper insulation, as conductors in the windings of electrical machines' magnetic circuits, the high DC potential stress of current machines can be mastered. The use of such a cable in the winding of the machines means, however, that classical machine, insulation, construction and manufacturing technology cannot be used directly. The use of such an extruded cable for AC has, however, already come into use as, for example, reported in WO 97/45919, "Rotating electric machines With magnetic circuit for high voltage and method for manufacturing the same".

The AC-DC inverters used in connection with the technology used in the SE 99044740-9, ie with AC machines with windings of cables with extruded insulation with high DC potential resistance, must also be insulated in view of the high DC potential to which they will be exposed. The problems that have been described in connection with the reporting of US 4057736 will thus be equally obvious also with regard to the AC-DC converters in an embodiment according to SE 99044740-9.

A similar problem with high DC potential is found in the so-called HVDC transmissions. Here, a number of converter modules are connected in series and are supplied with alternating voltage from so-called converter transformers. These are transformers that are different from conventional transformers in that they are oil-filled and equipped with special bushings so that the windings can withstand the high DC potential to which they are exposed from an insulation point of view. This problem is described, among other things, in WO 97/45907, "Rotating electrical plants". DESCRIPTION OF THE INVENTION According to the description of the technical advice, the present invention relates to electric power systems comprising at least two electric power plants with DC output, each including an AC machine and at least one AC-DC inverter, a DC transmission line and means for DC-AC conversion and that a series connection is formed of the DC outputs of the AC power plants AC-DC converters via intermediate transmission lines, the DC transmission line and the means for the DC-AC conversion. In such an electric power system, as previously pointed out, the electric power plants may be located at a high DC potential relative to earth in terms of insulation technology. The object of the invention is to provide the electric power plants' AC machines, with magnetic fl destiny carriers and live AC windings, as well as associated AC-DC inverters with control electronics with such a high DC insulation level that the risk of partial discharges, PD, or flashover between components and: between components and soil becomes minimal.

An electric power plant according to the invention comprises, as stated above, an AC machine and at least one AC-DC converter. When AC your AC ~ lDC inverters are used, these are preferably connected in parallel. In order to be able to account for the invention, here comes first a more detailed specification of these and their mutual connection. The AC machine comprises a driven shaft and is provided with magnetic current carriers with a winding with an accessible neutral point and with an AC output which is connected to an AC input of at least one AC-DC current rectifier with DC outputs.

In order to achieve the object of the invention, it further holds according to the invention that the AC machine, including the magnetic current carriers with the AC current windings, is arranged within a surrounding "inner" electric field control shell which is connected to high voltage DC potential. relative ground, for example with a high-impedance potential connection to the neutral point of the AC machine and a substantially concentric “outer” electric field-controlling shell to the inner shell with preferably a low-ohmic connection to ground. The housing and body of the AC machine are connected low to the inner shell. The potential differences within the rotating electric AC machine are thus kept down to such a level that is determined solely by the AC voltage generated in the rotating electric machine at low or medium voltage level.

- The AC-DC converter, including power semiconductors with live and current-carrying parts, such as connections, inductors, etc. and signal and control circuits, are arranged within a surrounding "internal" electric field control shell which is connected to high-voltage DC potential relative to the ground plane, e.g. a high-ohmic potential connection to the outputs of the AC-DC converter or instead only a high-ohmic potential connection from the neutral point of the AC machine, and a substantially concentric “outer” electric field control shell to the inner shell with preferably a low-angle connection to earth.

The housing and body of the AC-DC converter are low-coupled to the inner shell. The potential differences within the converter are thus kept down to such levels that are only determined by the AC voltage of the AC machine connected to the AC inputs of the converter. The potential differences within the converter will thus also be of the same order of magnitude as the rated voltage of the AC machine, - the shells must have an electrically conductive function. A more detailed description of the shells is given below the description of embodiments. the insulation between the inner and outer shells shall be dimensioned for the nominal voltage of the DC-AC o; The transducers to the AC power network, ie the corresponding nominal operating voltage between the terminals of the DC-AC inverter, provided that the outer housings are connected low to the ground plane, - the surrounding field control shells shall be provided with high voltage insulating bushings the transmission lines between the electric power plants and the transmission line between the nearest electric power plant and the return line should preferably be made with the previously mentioned extruded DC power cable, ie a cable with high DC potential resistance - the mechanical shaft of the driven AC machine must include an electrical insulation part against the shaft of a drive device in order to be able to galvanically separate the shaft of the AC machine from the ground potential.

In a preferred embodiment of the invention, both the AC machine and the AC-DC converter are placed within one and the same pair of surrounding inner and outer field control shells, with only the neutral point of the AC machine being high-impedance potential connected to the inner shell. Other embodiments will also be described in the description of embodiments.

An embodiment of an electric power plant / electric power system in accordance with the reported invention means that - the potential difference inside the electric power plant is of the same order of magnitude as the rated voltage of the AC machine - the AC component in the electric fields is of the same magnitude as the rated voltage of the AC machine and is kept internal 5 359555 in the electric power plant and its innermost enclosing high-voltage DC-insulated equipotential surfaces, ie the inner shell - the AC and DC insulation are thus separated from each other.

With the use of a high DC potential-resistant technology and high-frequency potential connections in electrically passive plant parts according to the invention, great advantages can be achieved both with rotary electric machines and converters which are exposed to high DC potential relative to earth. As for the AC machines, it has been reported during the state of the art how to proceed or intend to master these problems with, for example, extensive "supported (on) insulative structures of progressively greater height" or with special DC extruded insulated conductors with an internal and an outer semiconductor shield shields the windings of the magnetic current carriers. The great advantage of using a technique according to the invention relative to SE 9904740-9 and SE 9904753-2 is that the track insulation of the AC machine no longer needs to be performed for full DC voltage but can be dimensioned from the insulation voltage for the current rated voltage of the AC machine. This means that the AC machines can be manufactured with conventional and familiar insulation systems according to existing technology, - The AC-DC converters apply that power semiconductors, connections, inductors, filters, control circuits, computers, communication devices, etc. according to existing and conventional technology can be used directly inside it. inner shell without expensive redesigns to adapt to the high DC potential.

An advantage of using a technique according to the invention is thus that the criteria of the rotating AC machine and the AC-DC converter for dimensioning and insulation, resulting in the physical size, weight, weight, cost of the machine and the converter 515955 ll volume cost mm is completely determined by the current well-known ground voltage AC criteria.

Another advantage of embodiments according to the invention is that malfunctions in the electric power system caused by overheating will also be minimized with embodiments according to the invention.

A further and significant advantage of embodiments according to the invention is that the electric fields around electrically active, and / or passive plant parts, ie machines, converters, etc. can be determined at the design stage. The electric fields with respect to the DC part are controlled by equipotential surfaces in the shells and _ by equipotential surfaces in cables and cable accessories such as connectors and bushings. The touch guards are integrated in this way in the shells and cables with accessories.

A further advantage of embodiments according to the invention, in contrast to the state of the art reported, is that it is easy to arrange a bypass of a faulty electric power plant. This can be done with power electronics and, for example, only based on power semiconductors such as power diodes, which block due to reverse voltage during normal operation of the electric power system.

Another and extremely important advantage of embodiments according to the invention is that in addition to the use of a conventional earthing system, a "equipotential connection system" is obtained here and that these systems together allow a significant number of advantages over only so-called normal earthing. the combination of earthing and equipotential bonding systems as they may be applied to embodiments of the invention and the advantages which the combination allows will be described in the description of embodiments. according to the invention.

Figure 2 shows an alternative embodiment of an electric power plant according to the invention.

Figure 3 shows how a plurality of electric power plants according to the invention, together with a DC transmission line and means for DC-AC conversion of the DC power transmitted by the transmission line to a distribution or transmission network, can form a DC electric power system.

DESCRIPTION OF EMBODIMENTS A principal and preferred embodiment of an electric power plant according to the invention is shown in Figure 1. As discussed above, the idea is included. preferred embodiment an AC machine 1 and an AC ~ DC converter 2 within one and the same pair of shells, i.e. within an inner shell 3 and a, substantially: concentric thereto, outer shell 4.

The shells are fixed relative to each other with spacer insulators 5.

The space 6 between the housings is filled with gaseous and / or solid insulation. The outer shell is low-loosely connected to the ground plane 7.

The outer shell of the electric power plant is shown here placed on a bracket 8, for example belonging to a wind power plant. The AC machine is fixed via fastening devices 9 to the inner shell 3. Since the shaft 10 of the AC machine is to be galvanically separated from ground potential, the shaft consists of an electrically insulating part 11, preferably located in the space between the two shells. The driven part 12 of the shaft is mounted in a support 13. The rotor of the AC machine is shown here provided with a magnetizing winding 14 and the stator of the AC machine is provided with a Y-coupled three-phase winding 15 whose neutral point is via a resistance 16 high-impedance potential associated with the inner shell.

The converter 2 with associated control unit 17 and protection unit 18 is also fixed to the inner shell 3 via fastening devices 19.

The task of the control unit 17 is to control both the converter 2 and the rotor winding of the AC machine. In the embodiment shown, the electric power plant is intended to be controlled via a wireless communication link 20. The three-phase voltage of the AC machine generated in the stator winding is connected to the AC input of the converter. The two-pole DC output of the converter is led via the high-voltage insulating bushings 21 and 22 arranged through the shells via HVDC transmission lines 23 and 24 to the other electric power plants in the DC loop.

The cable forming the transmission lines is, as has been seen previously, provided with inner and outer semiconductor layers (not shown). As mentioned, the inner layer is in direct contact with the electrical conductor. The outer layer must have a galvanic connection to the outer shell and thus to the ground plane.

The fixed insulation of the cable is given, within the bushings 21 and 22 and further towards the DC outputs of the AC-DC inverter, preferably a conical stepping shape. The outer shell is suitably provided with a lightning conductor 7a which is connected together with the connection of the outer shell to the ground plane.

With regard to the design of the shells, it has been shown, as has been shown, that they must be electrically conductive. Another and mechanical requirement is that they must have a certain mechanical bearing capacity, especially with regard to the parts of the shells that are to support the AC machine and the AC-DC inverter with associated control and monitoring units.

From the point of view of electrical conductivity, there are a number of materials and combinations of materials that can be used. In addition to a purely electrically conductive, mechanically strong material in the form of sheet metal and the like, conductive plastic materials, conductive metallic nets applied to plastic materials, etc. can be used. An inner and an outer shell forming part of the same pair of shells may well be formed of different electrically conductive materials.

With regard to the mechanical bearing capacity, the thickness of the shells can be dimensioned depending on the current specific load. The parts of the shells that support the AC machine and AC-DC inverter should therefore suitably have a greater material thickness than the rest of the shell.

The mechanical bearing capacity of the shells thus also places corresponding demands on the design of the spacer elements which, in addition to allowing sufficient insulation distance, must also be able to absorb different mechanical loads.

Figure 2 shows an alternative embodiment where the AC machine 1 and the current rectifier 2 are placed in different pairs of shells 3a, 4a and 3b and 4b, respectively. Although the AC voltage to be transmitted between the different pairs of shells is, as has been shown in the report, significantly lower than the high DC potential to which the power plant will be exposed, this AC transmission, in the form of a transmission cable, must 23a, HVDC-insulated for maximum DC-V voltage. The same applies to the corresponding high-voltage insulating three-phase bushings 25a and 25b. Connection of the semiconductor layers is performed in the same way as shown for the corresponding figure in Figure 1. In order to potentially fix the DC outputs of the rectifier to the inner shell, in this embodiment both outputs must be connected to the inner shell via high-ohmic resistors 16a and 16b, respectively. The design of the two pairs of shells in terms of bearing capacity, intermediate insulation 6, fastening devices 9, 19 and other included installation parts such as spacer insulators 5, are similar to those described for figure 1. In alternative embodiments of the invention, the shells may be toroidal in shape. For such embodiments, the shells are preferably shaped so as to connect closely to the outer surrounding surface of the stator of the AC machine. In an embodiment corresponding to Figure 1, i.e. when the AC machine and AC-DC current rectifiers are within the same pair of shells, the converter, especially if designed as a diode rectifier, may very well be more or less integrated with the stator of the AC machine. In its simplest toroidal embodiment, only the AC machine is surrounded by a pair of toroidal shells, i.e. corresponding to shells 3a and 4a according to Figure 2. An advantage of toroidal shells is that the insulating shaft part 11 can be replaced by insulating spokes which can thus be dimensioned to take up was each its share of the driving moment on the shaft l2. This can be of great importance, especially in low-speed embodiments, where the shaft torque can be high for obvious reasons.

Embodiments of the electric power plants according to the invention allow, as indicated above, special and new "grounding systems" when together they form a DC series-connected electric power system. In order to be able to demonstrate one of the advantages when electric power plants according to the invention form an electric power system, the “grounding possibilities” that are available must be described on the basis of Figure 3.

Figure 3 shows an electric power system consisting of a number, two pieces shown here, electric power plants 26 and 27 shown in a somewhat simplified form of the electric power plants according to Figure 1 and Figure 2, an HVDC transmission line 28, a DC-AC inverter 29 for conversion of the transmitted DC power to a Y / D-connected transformer 30 for supplying a distribution or transmission network 31.

Since the DC-AC converter will be exposed to the same high DC potential as the electric power plants in general, it will also need to be placed within an inner shell 32 and a practically concentric with this outer shell 33. The electric power system is preferably grounded, ie has a connection over a resistive fault current limiting means to the ground plane at one point. According to Figure 3, this is done with a residual current limiting resistor 34 connected to the neutral point of the transformer winding. The neutral point also has a high-ohmic connection 35 to the inner shell 32. The outer shells of all electric power plants are directed via the connections 36 and 37. The corresponding direct arrangement of the outer shell 33 of the AC-DC converter takes place via the connection 38. The neutral point of the winding of the AC machines 39 and 40 are connected via high-ohmic connections 16c and 16d to their own inner shell 3c and 3d, respectively, which each form their own inner reference plane. This means that a resistive residual current limiting, normally electroless, equipotential connection is formed at each electric power plant between the neutral point of the AC machines' windings and the reference plane, ie the inner shell.

Both the housing and the body of the AC-DC inverter are, as mentioned earlier, low-coupled to the inner shell.

The advantages that these "earthing systems" allow include that - hazardous fault currents to ground plane or reference plane are eliminated - unintentional voltage to ground plane or reference plane is eliminated - person and property are protected - electric power plants and power systems are protected against existing surges / transients - electric power plants and electric power systems are protected against discharges of static electricity - electric power plants and electric power systems are protected against thunder 00 0000 00 0 0 0 0 000 0000 000 0 IIO 0 0 0 0 00 OO 000 00 20 25 30 35. . . . .- une nu l7 Together, these “earthing systems” ensure conversion from alternative energy to electrical energy and ensure the transmission of energy. They also facilitate the possibilities for monitoring, measurement, fault disconnection and signal transmission.

Claims (21)

1. 20 25 30 515953 »18 PATENTKRAV al. Electric power plant comprising an AC machine (1) via a driven shaft (10) provided with a winding (15) with an accessible neutral point and with AC output connected to an AC input of at least one AC-DC converter (2) with DC outputs and pairs of field control shells (3, 4, 3a, 4a, 3b, 4b) are characterized in that the shells are arranged substantially concentrically around each other such as an inner shell (3, 3a, Elb) and an outer shell. (4, 4a, 4b) and that the AC machine and the converter (s) are arranged surrounded by the inner shell. Electric power plant according to claim 1, characterized in that the shells are arranged as a first (3a, 4a) and a second (3b, 4b) pair of shells, each shell of the two pairs of shells being arranged substantially concentrically around each other. such as an inner (3a, 3b) shell and an outer (4a, 4b) shell and that the AC machine is arranged surrounded by the inner shell of the first pair and that the AC-IIC rectifier (s) are arranged surrounded by the the other pair's inner shell. - Electric power plants according to claims 1 and 2, characterized in that the shells are toroidal in shape. Electric power plant according to claims 1 and 2, characterized in that the connection between the AC output of the AC machine and the AC input of the AC-DC converters (s) when the AC machine and the AC-DC converter (s) are arranged in different pairs of shells is arranged with an HVDC-insulated power cable (23a). Electric power plant according to the preceding claim, characterized in that when both the AC machine and the AC-DC inverter / s are included in the same pair of shells and when the AC-DC converter / s are included in a second pair of shells are The DC outputs of the AC-DC rectifiers / 25 are connected to HVDC-insulated power cables output via the two shells (23, 24). in Electric power plant according to the preceding claims, characterized in that the HVDC-insulated power cable consists of an electrical conductor surrounded by an inner semiconducting layer, an insulating layer of extruded plastic surrounded by an outer semiconducting layer and outer mechanical protection. . 7. Electric power plant according to the above claims, characterized in that the HVDC-insulated power cable consists of an electrical conductor surrounded by paper insulation impregnated with viscous oil and external mechanical protection (MIND cable). Electric power plant according to claims 1 and 2, characterized in that the shells are electrically conductive. 9. Electric power plants according to claims 1, 2 and 8, characterized in that the shells are made of a metallic electrically conductive material. 10. Electric power plants according to claims 1, 2 and 8, characterized in that the shells are made of a metallic electrically conductive network embedded in a non-conductive plastic material. Electric power plant according to claims 1, 2 and 8, characterized in that the shells are made of an electrically conductive plastic material. Electric power plant according to claims 1 and 2, characterized in that the neutral point of the AC machine is high-impedance connected to an inner shell (3, 3a, 3b). Electric power plant according to claims 1 and 2, characterized in that when the AC machine and the AC-DC inverter are arranged in different pairs of shells, the DC outputs of the AC-DC inverters are via 20 35 ø IQ uo: ui 515953 20 high-resistance resistors (16a, 16b) connected to the second pair of shell inner shells (3b). 14. An electric power plant according to claim 1, characterized in that the outer shell is connected to a ground plane. Electric power plant according to claims 1, 2 and 13, characterized in that when the AC machine and the ACDC inverter (s) are arranged in separate pairs of shells, the outer shell of the two pairs of shells are connected to the ground plane. Electric power plant according to claims 1 and 2, characterized in that the field control shells are provided with high-voltage HVDC-insulating bushings (21, 22) for output HVDC-insulated power cables (23, 24). Electric power plant according to claims 1, 2, 4, 5 and 6, characterized in that the outer semiconducting layer of the HVDC-insulated power cables is connected to the outer shell of the pair. Electric power plant according to the preceding claims, characterized in that the driven shaft (10) of the AC machine is provided with an electrically insulating part (11). Electric power plant according to claims 1 and 2, characterized in that in each pair of shells the shells are fixed relative to each other with spacer insulators (5). Electric power plant according to claims 1 and 2, characterized in that the space between an inner shell and an outer shell of a pair of shells is filled with gaseous and / or solid insulation. Electric power plants according to claims 1 and 2, characterized in that lightning conductors (7a) are connected to the outer shells. KN 8923 SE