Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
  • H01F27/00—Details of transformers or inductances, in general
  • H01F27/28—Coils; Windings; Conductive connections
  • H01F27/288—Shielding
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02K—DYNAMO-ELECTRIC MACHINES
  • H02K3/00—Details of windings
  • H02K3/32—Windings characterised by the shape, form or construction of the insulation
  • H02K3/40—Windings characterised by the shape, form or construction of the insulation for high voltage, e.g. affording protection against corona discharges
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
  • H01F27/00—Details of transformers or inductances, in general
  • H01F27/28—Coils; Windings; Conductive connections
  • H01F27/32—Insulating of coils, windings, or parts thereof
  • H01F27/323—Insulation between winding turns, between winding layers
• • H—ELECTRICITY
  • H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
  • H02K—DYNAMO-ELECTRIC MACHINES
  • H02K2203/00—Specific aspects not provided for in the other groups of this subclass relating to the windings
  • H02K2203/15—Machines characterised by cable windings, e.g. high-voltage cables, ribbon cables

Definitions

• the present invention relates to an insulation for, and a method for insulation of, a conductor arranged in a plurality of turns for generation of a magnetic field.
• the invention relates to an insulation in an electric circuit in a rotating electrical machine.
• a rotating electrical machine is meant an apparatus which converts electrical energy into mechanical energy or vice versa.
• Such an apparatus comprises an electric circuit, a magnetic circuit, and a mechanical circuit.
• the mechanical circuit comprises two bodies which are movable in relation to each other. Upon a forced mechanical movement, a magnetic field is generated which is converted by the electric circuit into electrical energy. When supplying electrical energy, a magnetic field is generated which is converted by the mechanical circuit into mechanical energy.
• a rotating electrical machine as used in the following text, are meant both a generator and a motor.
• the invention is preferably intended to be applied to a rotating electrical machine acting under high current and under high voltage, such as, for example, a generator which produces electric power.
• the mechanical circuit here comprises a stator and a rotor, whereby the rotor is rotatable in relation to the stator with one degree of freedom.
• the electric circuit may be arranged as a winding in either the rotor or the stator, or in both. By electrifying a winding, a magnetic field arises between the rotor and the stator.
• the magnetic field may be controlled and amplified by arranging magnetic cores in the stator and the rotor, which magnetic cores may be composed of, for example, laminated stacks of magnetically oriented sheets.
• the invention is not limited to an application on rotating electrical machines only, but may also be used in any electrical machines or apparatus in which a conductor is to be insulated to be able to handle high voltages.
• a rotating machine in the form of a generator will be briefly described here.
• the most frequently used type of generator in force applications is a so-called synchronous machine.
• Such a machine comprises a rotatably journalled rotor with a rotor winding surrounded by a stationary stator with a stator winding.
• Both the rotor and the stator comprise magnetizable material, which preferably consists of laminated stacks of sheet.
• the stator winding is arranged in radially embedded slots in the stator.
• the slots are axially oriented and rotationally symmetrically distributed along the stator.
• the stator winding comprises one or more series-connected conductors which are arranged in coils, which are located in the slots with two coils per slot.
• a variation of the inductance across the cross section of the winding conductor arises .
• the greatest reactance is obtained at the bottom of the conductor and the main part of the current then tends to flow at the top of the conductor.
• the conductor is divided into a plurality of strands which are insulated from one another.
• the division into strands does not prevent the inductance from varying for the different strands, but these have to be transposed, that is, change places. Such a transposition is usually carried out outside the stack of sheets but may also be arranged in the slots by means of a so-called Roebel transposition.
• the choice of strand dimensions is a compromise between electrical and mechanical requirements. From an electrical point of view, it is preferable to have many strands since this reduces the current displacement, but from a mechanical point of view, the coils may become more difficult to manufacture and install. Few strands with large dimensions result in problems when, for example, a conductor is to be bent.
• thermal, electrical, environmental and mechanical stresses must be taken in to consideration. These are usually called TEAM (Thermal, Electrical, Ambient and Mechanical) and influence the life of the insulation to a greater or smaller extent.
• TEAM Thermal, Electrical, Ambient and Mechanical
• the insulation shall allow a temperature increase which may comprise 0-180°C within one hour.
• the insulation shall permit a satisfactory electrical insulation without causing concentrations of the electric field.
• the insulation shall not be influenced by dirt, ozone or condensation.
• the insulation, from the environmental point of view entail any environmentally harmful emissions during manufacture or operation, and, during scrapping, be capable of being recycled.
• the insulation shall allow the coils to be fixed to the stator but still allow movement during thermal expansion of the conductor and insulating material.
• the coil itself must withstand the entire phase voltage which may amount to several kV. To this end, the coil is insulated against the stator by a main insulation.
• a partial discharge, or PD easily arises, because of deformations of the field in the high electric field strength, this partial discharge being commonly referred to as corona.
• corona When corona occurs, ozone (0 3 ) arises, among other things, which is very aggressive towards organic compounds.
• corona causes a weakening of organic insulating materials and the main insulation therefore includes materials which are corona-resistant.
• One such material is mica, which is an inorganic compound and which withstands the attack of ozone.
• the most commonly used insulating materials contain mica as main component.
• the mica is often embedded into a binder which is arranged on a tape-formed carrier.
• the material of the carrier and the binder may vary.
• a common embodiment of the main insulation is in the form of resin- saturated tapes containing flakes of mica, which are wound around the conductor and then cured in a furnace procedure.
• a corona protector is arranged, which is to prevent external corona between the coil side and the slot wall.
• Mica is a very brittle material which has low shear strength. Mica also has a thermal expansion which is one- fifth of, for example, that of copper.
• the conductor which is often made of copper, then tends to expand more than the insulation. Between the conductor and the insulation, a voltage thus arises because of the different thermal properties of the materials. Since mica has lower shear strength, fractures thus arise, which give rise to cavities in the insulation. Eventually, the cavities are filled with air and give rise to considerable deformations of the electric field. At such field concentrations, corona arises.
• an insulation for a generator is previously known, the main task of which is to arrange, in contact with the outside of the main insulation, a layer which is capable of diverting charges to minimize corona.
• the insulation is surrounded by a semiconducting layer of a curable glass-fibre coating.
• This coating replaces a prior art grounding tape, which had the ability to divert charges for preventing corona.
• the new coating is stated to conform to the contour of the insulation in a better way and to better retain its semiconducting properties after the curing of the main insulation.
• the semiconducting layer is applied to the upper and lower end regions of a coil on the inside of the main insulation. This embodiment is stated to entail an equalized electric equipotential around the ends .
• the known insulation does not add anything new to the prior art technique. Thus, it was already previously known to divert charges by arranging a semiconducting layer outside the insulation.
• a certain amount of corona is accepted and instead the insulation is brought to contain mica which withstands discharges. As discussed above, mica has inferior mechanical properties. When the discharges occur, ozone is formed which attacks carriers and binders of the insulation, gradually resulting in the insulation bursting. Thus, after a certain time, the stator winding with the insulation must be replaced.
• the object of the invention is to produce an insulation for a conductor arranged in a plurality of turns for generating a magnetic field.
• the invention relates to an insulation, arranged at a rotating elec- trical machine, which eliminates the occurrence of partial discharges (PD) and which has a long service life.
• the insulation shall also entail reduced maintenance and be more reliable than previously known insulation systems. From an environmental point of view, the insulation shall entail less environmentally harmful emissions during manufacture, use as well as scrapping.
• the object of the invention is also to suggest a method for insulation of a rotating electrical machine while achieving the objectives stated above. The insulation is in particular suitable when replacing a winding for an existing electrical machine .
• An electrical insulation is a medium or a material which, when placed between conductors of different potential, allows only a small or insignificant current to pass therethrough. At an increased potential between the conductors, also the electric field strength across the insulation increases . This also increases the risk of breakdown since the dielectric strength of the material is exceeded. The electric strength is defined as the maximum voltage gradient which the material is able to withstand without breakdown occurring.
• the dielectric breakdown for a gas is a result of an exponential multiplication of free electrons induced by the applied electric field.
• breakdown occurs at a voltage which is a function of the product of pressure and distance.
• a gas has a high breakdown strength.
• an electron accelerated by the electric field is not able to pick up sufficient acceleration for starting a breakdown by collision with other electrons.
• the number of electrons is too small in order for a sufficient number of collisions to take place.
• the dimensioning dielectric strength for a gas is about 0.5 kV/mm. At lower electric field strengths, thus, no corona occurs in gas-filled cavities in the insulating material or between conductors and insulation.
• the insulation according to the invention comprises an elongated tubular insulant intended to enclose a conductor.
• the insulant has one inner and one outer semicon- ducting layer adapted to contain between themselves an electric field.
• the semiconducting layers cover the inside and the outside, respectively, of the insulant and are joined to the insulant with such an adhesion that the materials accompany each other in case of a structural change caused, for example, by thermal or mechanical stresses.
• the joint must not contain cavities, neither during manufacture nor in cases of stresses on the joined-together materials.
• Such an adhesion between the insulant and the two semiconducting layers is achieved by manufacturing them from the same materials.
• a joint with the adhesion aimed at may be achieved by heat treatment of the materials such that they float together at the joint into a homogeneous structure. Mechanical or thermal changes between the insulant and the two semiconducting layers are then absorbed as elastic or plastic deformations in the materials nearest the joint.
• the inner layer is adapted to be galvanically or capa- citively coupled to the conductor and the outer layer is adapted to be connected, for example, to ground or another controllable potential, whereby the electric field arisen between the conductor and ground is enclosed between the semiconducting layers in the insulation. Any cavities which may arise inside the insulation, because of a change in temperature or mechanical influence, do not give rise to any occurrence of PD. Between the conductor and the inner semiconducting layer, there is no potential difference.
• the insulant may be made of an organic material without any addition of mica.
• the full insulating capacity of the material may then be utilized. Since no ozone is formed which may weaken the materials, the thickness of the insulation may be made smaller.
• the insulation may therefore be made of a homogeneous material, for example a thermoplastic resin or a rubber mixture.
• One such suitable material is a crosslinkable polyethylene.
• the semiconducting materials may be made of the same material and be brought to contain a conducting dust, for example carbon black or powdered coal.
• the insulant with the two semiconducting layers may hence in a simple manner be applied to the conductor by, for example, extrusion.
• the insulation system is especially intended for coils with a plurality of conductors, which may be divided into strands.
• the conductor and strand insulation is suitably made of a material which has a higher permittivity than the main insulation.
• an electrical rotating machine is subjected to an electric shock.
• the voltage then rises in the winding.
• the potential difference may then amount to a few tens of kilovolts.
• Each conductor strand is surrounded by a thin strand insulation which is adapted to insulate the conductor strands from each other.
• the strand insulation is usually adapted to exhibit a good short-term strength against electric flashovers.
• Two conductor strands are thus insulated from each other with an insulation thickness corresponding to two strand insulations.
• two layer thicknesses of this insulation are arranged.
• an insulation according to the invention encloses a plurality of conductors
• the insulation between the semiconducting layer and a conductor strand making contact therewith constitutes the thickness of the actual strand insulation only.
• the semiconducting layer is suitably connected to one of the conductor strands belonging to one of the conductors.
• the potential difference between the semiconducting layer and the conductor strand positioned nearest thereto is then only a few hundred volts during normal operation.
• the strand insulation constitutes sufficient insulation for preventing a flashover. In case of a shock, the potential increases instantaneously to several kilovolts. However, this potential change does not have time to develop into full strength in the semiconducting layer, so probabaly no flashover occurs in this case either.
• each conductor including all the conductor strands, may be coated with an extra layer of high- quality insulating material.
• Figure 1 shows a cross section through a coil for a stator winding which comprises an insulation according to the invention
• Figure 2 shows a cross section of an insulation according to the invention with a circular cross section, said insulation enclosing two conductors.
• FIG. 1 A cross section through a typical winding coil for a rotating electrical machine is shown in Figure 1.
• the winding comprises a first conductor with a plurality of strands 2 and a second conductor also with a plurality of strands 3.
• the strands belonging to the respective conductor are surrounded by a strand insulation 4, which thus forms an insulating layer surrounding the stack of conductor strands.
• Surrounding the strand insulation 4 is an insulation 1, which comprises an insulating intermediate layer 6 with an inner semiconducting layer 5 and an outer semiconducting layer 7.
• Figure 2 shows a cross section of an insulation 1 which encloses a first conductor 11 comprising a plurality of conductor strands 2 and a second conductor 12 comprising a plurality of conductor strands 3.
• the first conductor is surrounded by an insulating layer 9 and the second conductor is surrounded by an insulating layer 10.
• the surrounding insulation 1 comprises an insulating intermediate layer 6, an inner semiconducting layer 5 and an outer semiconducting layer 7.
• the different layers have been intentionally made thick so as to emphasize them.
• the semiconducting layers are thin and the insulating layers enclosing the conductor and the conductor strands are very thin.
• the insulating layers tend to be compressed into a homogeneous insulation surrounding conductors and conductor strands .
• One conductor strand 8 is galvanically or capacitively coupled to the inner semiconducting layer 5, such that this layer assumes the same potential as the conductor strand 8.
• the outer semiconducting layer 7 is in electrical connection with ground.
• the insulation 1 is brought to contain the electric field which is formed between the conductor and ground.
• no cavities are formed between the inner semiconducting layer and the outer semiconducting layer.
• the insulating layer and the two semiconducting layers must be homogeneous and be in absolute mechanical contact with one another. The mechanical contact must also be maintained in case of a change caused by temperature variation or mechanical influence.
• the outer semiconducting layer is adapted to distribute the ground potential across the outer limiting surface of the insulation.
• the outer semiconducting layer must thus cover the entire envelope surface.
• the inner semiconducting layer is adapted to distribute the phase voltage connected to the conductor across the inner limitation of the insulation.
• the inner semiconducting layer must thus cover the entire inner limiting surface of the insulation.
• the term semiconducting material means a material which has considerably less conducting properties than a conductor but which still does not have such poor conducting properties that it may be regarded as an insulant.
• the material included in the two layers may have a resistivity in the interval 10 "4 ⁇ - 10 4 ⁇ m, and especially in the interval 1 ⁇ cm - 100 ⁇ m.
• the insulating intermediate layer is arranged from an insulating material which has a high electric strength, for example in excess of 7 kV/mm.
• the insulating intermediate layers may thus be arranged from an organic material, for example a thermoplastic resin or a rubber mixture.
• the two semiconducting layers may advantageously be made of the same material as the insulating intermediate layer, in which case a conducting dust, such as carbon black or powdered coal, is mixed into it.
• a suitable material is, for example, a cross-linkable polymer.
• the insulating material no longer has to be supplied by winding.
• the polymeric material is advantageously supplied by extrusion, in which case the two semiconducting layers are supplied in the same process. This guarantees that cavities are completely excluded. It is not necessary for the insulant and the semiconducting layers to be made of the same materials . The decisive point is that no cavities arise between the materials.
• two separate materials may be joined together in such a way that the adhesion between them is maintained during thermal or mechanical influence . In case of materials with different properties, stresses arise in the region around the joint since one of the materials tends to expand more than the other. The adhesion should therefore be so strong that the joint is able to absorb these stresses.
• polymeric material is that it is deformable and may be subjected, during its service life, to repeated mechanical deformation without jeopardizing the adhesion between the layers. Such materials may be simply fused together while supplying heat, such that the materials float together and form a homogeneous joint without cavities.
• the strand insulation 4 is advantageously arranged with a dielectric constant which is higher than the dielectric constant for the main insulation.
• the strand insulation causes a change of the electric field such that the equipotential lines are displaced in a radial direction.
• the concentration of the electric field which would otherwise be greatest nearest the conductor, is thereby displaced out from the centre and occurs in the main insulation between the two semiconducting layers.
• a larger distance from the centre also implies that the electric field is distributed over a larger area, which further weakens the concentration.
• an insulating layer is arranged around each conductor.
• the potential difference between conductor strands associated with different conductors may, in the event of a shock, amount to a few tens of kilovolts.
• the short-time strength against flashovers of a simple layer of strand insulation is usually not sufficient for stopping a flashover between the conductor strand and the semiconducting layer.
• the conductors are enclosed by an extra insulating layer 9, 10. It is also possible to create sufficient safety against flashovers by providing the inner semiconducting layer with such a resistance that no harmful potential is able to propagate in case of a shock.

Landscapes

• Engineering & Computer Science (AREA)
• Power Engineering (AREA)
• Insulation, Fastening Of Motor, Generator Windings (AREA)
• Insulating Bodies (AREA)
• Coils Of Transformers For General Uses (AREA)
• Insulating Of Coils (AREA)
• Regulation Of General Use Transformers (AREA)
• Cable Accessories (AREA)

Applications Claiming Priority (3)

Publications (1)

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• 1997
  • 1997-09-30 SE SE9703565A patent/SE510590C2/sv not_active IP Right Cessation
• 1998
  • 1998-09-29 AU AU92908/98A patent/AU728661B2/en not_active Ceased
  • 1998-09-29 ZA ZA988894A patent/ZA988894B/xx unknown
  • 1998-09-29 CN CN98809635A patent/CN1272239A/zh active Pending
  • 1998-09-29 WO PCT/SE1998/001715 patent/WO1999017425A1/en not_active Application Discontinuation
  • 1998-09-29 BR BR9812543-5A patent/BR9812543A/pt not_active Application Discontinuation
  • 1998-09-29 KR KR1020007002713A patent/KR20010023988A/ko not_active Application Discontinuation
  • 1998-09-29 EP EP98945732A patent/EP1020003A1/en not_active Withdrawn
  • 1998-09-29 AR ARP980104874A patent/AR016940A1/es unknown
  • 1998-09-29 CA CA002304525A patent/CA2304525A1/en not_active Abandoned
  • 1998-09-29 JP JP2000514377A patent/JP2001518775A/ja active Pending
  • 1998-09-29 PL PL98338927A patent/PL338927A1/xx unknown

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