EP2463870A1 - Trockenwandler mit Hitzerohr in der Hochspannungswickelung - Google Patents

Trockenwandler mit Hitzerohr in der Hochspannungswickelung Download PDF

Info

Publication number
EP2463870A1
EP2463870A1 EP10194530A EP10194530A EP2463870A1 EP 2463870 A1 EP2463870 A1 EP 2463870A1 EP 10194530 A EP10194530 A EP 10194530A EP 10194530 A EP10194530 A EP 10194530A EP 2463870 A1 EP2463870 A1 EP 2463870A1
Authority
EP
European Patent Office
Prior art keywords
heat pipe
voltage coil
pipe evaporator
high voltage
evaporator
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP10194530A
Other languages
English (en)
French (fr)
Inventor
Cherif Ghoul
Daniel Chartouni
Jaroslav Hemrle
Lilian Kaufmann
Patrick Kaufmann
Peter Unternaehrer
Rafael Murillo
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
ABB Research Ltd Switzerland
ABB Research Ltd Sweden
Original Assignee
ABB Research Ltd Switzerland
ABB Research Ltd Sweden
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by ABB Research Ltd Switzerland, ABB Research Ltd Sweden filed Critical ABB Research Ltd Switzerland
Priority to EP10194530A priority Critical patent/EP2463870A1/de
Publication of EP2463870A1 publication Critical patent/EP2463870A1/de
Withdrawn legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F27/00Details of transformers or inductances, in general
    • H01F27/28Coils; Windings; Conductive connections
    • H01F27/32Insulating of coils, windings, or parts thereof
    • H01F27/327Encapsulating or impregnating
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F27/00Details of transformers or inductances, in general
    • H01F27/08Cooling; Ventilating
    • H01F27/10Liquid cooling
    • H01F27/18Liquid cooling by evaporating liquids
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F27/00Details of transformers or inductances, in general
    • H01F27/28Coils; Windings; Conductive connections
    • H01F27/2876Cooling

Definitions

  • the invention relates to a method of manufacturing a dry type transformer.
  • the invention relates to a method of manufacturing a dry type transformer with a heat pipe evaporator.
  • the invention relates to a dry type transformer manufactured by the method and to the use of a dry type transformer manufactured by the method for a wind energy plant.
  • Thermal issues may be an important limitation when attempting to improve the design of dry type transformers towards size reduction and increased power rating. Thermal losses due to the resistance of the conductors of transformer windings as well as transformer core losses may cause the transformer to heat up. The maximum power of the transformer is thus limited by the allowed maximum temperature of the transformer. If cooling of the transformer can be improved, the same transformer may be operated with higher power rating, or a smaller transformer may be used for a certain required power. Both options may result in material and cost saving. Active cooling with fans or dedicated air circulation channels may be used for cooling dry type transformers as well as cooling the dry type transformers utilizing heat pipes.
  • Manufacturing dry type transformers with cooling devices may be complex and costly.
  • a method of manufacturing a dry type transformer with a heat pipe evaporator, at least one high voltage coil, at least one low voltage coil, and a core with at least one limb comprises the steps of providing a hollow cylindrical heat pipe evaporator, winding the at least one high voltage coil onto the heat pipe evaporator around a longitudinal axis of the heat pipe evaporator, and placing the at least one low voltage coil such that the heat pipe evaporator is positioned between the at least one high voltage coil and the at least one low voltage coil.
  • the heat pipe evaporator is designed to remove heat from the at least one high voltage coil and from the at least one low voltage coil, and is adapted to dielectrically insulate the at least one high voltage coil from the at least one low voltage coil.
  • An air gap may be provided between the at least one high voltage coil and the at least one low voltage coil, the air gap being adapted to dielectrically insulate the at least one high voltage coil from the at least one low voltage coil.
  • a high voltage transformer coil is wound around a cylindrical hollow heat pipe evaporator comprising two concentric tubes forming a cavity, and the low voltage coil of the transformer is placed within an inner wall of the hollow cylindrical heat pipe evaporator such that the heat pipe evaporator is separating the high voltage coil from the low voltage coil.
  • Such a method may provide for an efficient and simple manufacturing of the dry type transformer with an effective connection of the heat pipe evaporator to the transformer high voltage coil, wherein the connection of the heat pipe evaporator may be easily integrated in the manufacturing process of the dry type transformer.
  • the manufactured dry type transformer may require less space than a transformer with a cooling system utilizing fans or dedicated air circulation channels and may be more efficiently manufactured than dry type transformers with such cooling systems.
  • the contact area of the high voltage coil and the heat pipe evaporator may be provided along the whole length of the wound high voltage coil to efficiently remove heat from the high voltage coil to the heat pipe evaporator.
  • the heat pipe evaporator may be attached to the coil such that an optimal thermal contact with the high voltage coil is established to efficiently exchange or remove heat from the coil to the heat pipe evaporator.
  • Dry type transformers manufactured by winding the high voltage coil directly onto such a heat pipe evaporator may be realized in a compact, room-saving way enabling an optimal size performance ratio.
  • the hollow cylindrical heat pipe evaporator is comparably easy to seal at a top and bottom end of the evaporator, which is important for long-term operation of the heat pipe. Since a high voltage coil of a transformer produces most of the heat of a transformer, the cooling of the high voltage coil may advantageously provide for an efficient removing of heat from the transformer from the place where most of the heat of the transformer is produced during operation.
  • the heat pipe evaporator may be pre-fabricated or manufactured in a further step of the method.
  • the heat pipe evaporator may also be readily manufactured and provided for the method.
  • the heat pipe evaporator may have the form of a hollow cylinder and may be made of a material selected from the group consisting of a glass fibre reinforced epoxy, an epoxy, or any insulating material with a thermal expansion similar to the thermal expansion of epoxy or differing from the thermal expansion of epoxy within a range of up to 20%.
  • the dry type transformer may be a dry type transformer with a voltage in a range from 1 kV - 75 kV.
  • the heat pipe evaporator length in a direction of the longitudinal axis of the heat pipe evaporator equals a high voltage coil length in this direction.
  • the cavity of the heat pipe evaporator may have a radial thickness of at least 2 mm, thus enabling an optimal heat removal from the high voltage coil and the low voltage coil by the heat pipe evaporator.
  • a cavity with a small thickness of a few millimetres may provide for a small volume of the evaporator while at the same time providing enough volume for the working fluid or coolant of the evaporator to efficiently remove heat from the high voltage coil and the low voltage coil via the heat pipe evaporator. Since the evaporator is arranged between high voltage coil(s) and low voltage coil(s) such a cavity thickness of the evaporator of a few millimetres may provide for the necessary dielectric requirements.
  • the radial thickness of the cavity is proportional to the amount of heat needed to be moved from the high voltage coil and the low voltage coil of the transformer to the heat pipe.
  • the thickness of the cavity may be adapted according to the performance of the transformer or the required power of the transformer which causes the heat of the transformer during operation.
  • the heat pipe evaporator is thermally coupled to the at least one high voltage coil by removing heat from the at least one high voltage coil and the heat pipe evaporator is simultaneously adapted to remove heat which is emitted by the at least one low voltage coil from the at least one low voltage coil.
  • the method further comprises arranging the heat pipe evaporator over a winding mandrel before the winding of the at least one high voltage coil.
  • the winding process may be optimized since the cylindrical hollow heat pipe evaporator may be adapted to the size of the mandrel which is used for winding the at least one high voltage coil around the mandrel during the manufacturing process of the dry type transformer.
  • the method further comprises the step of arranging the at least one low voltage coil on an inner concentric tube of the heat pipe evaporator, wherein the at least one high voltage coil is wound to an outer concentric tube of the heat pipe evaporator.
  • an air gap may be provided between the at least one high voltage coil and the at least one low voltage coil, the air gap being adapted to dielectrically insulate the at least one high voltage coil from the at least one low voltage coil.
  • the high voltage and low voltage coils By arranging the high voltage and low voltage coils on the outer and inner concentric tubes of the hollow cylindrical or in other words ring cylindrical shaped heat pipe evaporator an optimal heat removal from the high voltage and low voltage coils may be provided, as the coils are in direct contact with the concentric tubes forming the cavity of the heat pipe evaporator.
  • the at least one low voltage coil and the at least one high voltage coil with the heat pipe evaporator are arranged around the at least one limb of the transformer.
  • the coils may be arranged efficiently and easily over the limb of the core of the transformer.
  • the low voltage coil may be arranged to the limb separately and then the heat pipe evaporator with the thereto wound high voltage coil may be placed around the limb or the limb with the thereto arranged low voltage coil may be inserted within the evaporator.
  • the method further comprises the step of pre-fabricating the heat pipe evaporator, wherein the pre-fabricating comprises: manufacturing an inner concentric tube with spacers which are attached to the inner concentric tube and spaced apart from each other, manufacturing an outer concentric tube, attaching the outer concentric tube onto the spacers of the inner concentric tube such that the cavity is provided between the outer concentric tube and the inner concentric tube, the cavity acting as the heat pipe evaporator.
  • Such a pre-fabricating of the heat pipe evaporator may improve the efficiency of manufacturing the dry type transformer since the production of the heat pipe evaporator may be easily integrated in the dry type transformer manufacturing process and may result in cost savings also for manufacturing the heat pipe evaporator since only at least two spacers may be needed between the inner and outer concentric tubes by providing inner and outer concentric tubes with rigid material such as glass fibre reinforced epoxy or any rigid and insulating material with thermal expansion coefficient close to the one of epoxy.
  • the heat pipe evaporator comprises an inner concentric tube with a first diameter and comprises an outer concentric tube with a second diameter, wherein the inner concentric tube features a surface structure to strengthen the heat pipe evaporator and to reduce working fluid volume.
  • the inner concentric tube may comprise spacers spaced apart from each other to create the cavity of the heat pipe evaporator when the outer concentric tube is attached to such spacers.
  • the spacers may be spaced apart from each other by a first distance in a circumferential direction of the inner concentric tube.
  • the step of pre-fabricating the heat pipe evaporator comprises the step of attaching a liquid return tube to the cavity of the heat pipe evaporator, the liquid return tube being adapted to enable a separate liquid return flow of a coolant in a direction from an condensor to a bottom part of the cavity.
  • the liquid may flow from any part within the tube to a lower located part within the tube.
  • the liquid return tube may be adapted to enable a separate liquid return flow of a coolant from the heat pipe condenser to a bottom part of the cavity, wherein the tube inlet is at the condenser and the tube outlet is at the bottom part of the cavity.
  • the heat pipe evaporator may be pre-fabricated including a polytetrafluorethylene (PTFE) liquid return tubing attached to the inner cavity of the hollow cylinder.
  • the PTFE tubing enables a separate liquid return flow of the coolant from the heat pipe condenser, while the coolant vapour ascends through a second pipe attached to the evaporator top outlet after manufacturing of the high voltage coil.
  • the PTFE tube is attached to the inner cavity of the hollow cylinder such that the tube outlet is at the bottom of the cavity, enabling the liquid to flow to the very bottom of the cavity.
  • Such a flow separation of coolant liquid and vapour may improve the performance of the heat pipe by preventing the two phases from blocking each other which is the case when they flow through the same tube.
  • the method further comprises the step of closing a top gap and a bottom gap of the heat pipe evaporator at a top end and at a bottom end of the heat pipe evaporator by arranging a top sealing ring in the top gap and by arranging a bottom sealing ring in the bottom gap.
  • a tight and sealed heat pipe evaporator may be provided enabling an optimal heat exchange from the high voltage coil and the low voltage coil of the transformer to the evaporator and thus to a heat pipe since no liquid or vapour of the working fluid of the evaporator may escape the heat pipe evaporator within a heat pipe cycle.
  • the step of closing the top and bottom gaps by the top and bottom sealing rings may happen before the placement of the at least one low voltage coil.
  • the top and bottom sealing rings have a wedge-like cross-sectional shape to facilitate attaching (gluing) the sealing rings in the gaps between the two tubes of the heat pipe evaporator. This may ensure more efficiently the tightness and the sealing of the heat pipe evaporator, since the contact area between the sealing rings and the gaps may be enlarged.
  • the top gap and the bottom gap may have a form matching the form of the top and bottom sealing rings in order to provide a large contact area with the sealing rings.
  • the top and bottom gaps may have a radial distance smaller than the radial thickness of the cavity.
  • the inner concentric tube may have a circumferential protrusion in a radial direction at the top end and at the bottom end of the evaporator with a protrusion length in the radial direction which equals the thickness of the cavity such that no sealing rings are needed to tighten or to seal the heat pipe evaporator since the outer concentric tube may be attached to the inner concentric tube and to these protrusions and thus effectively seal the cavity.
  • the spacers may be glued to the inner concentric tube or may be integrated in the manufacturing of the inner concentric tube, such as by removing cavities between the spacers from a one piece inner concentric tube during the manufacturing process of the inner concentric tube.
  • the method further comprises the step of adding a reinforcement material to the wound at least one high voltage coil.
  • the wound high voltage coil may be mechanically stabilized.
  • a sealed evaporator may be provided enabling an optimal heat exchange from the coil and the transformer within the heat pipe since no liquid or vapour may escape the heat pipe evaporator within the heat pipe cycle.
  • the reinforcement material is selected from the group consisting of glass fibre nets or rigid foils,
  • the method further comprises the step of casting the at least one high voltage coil and the heat pipe evaporator such that a casted high voltage coil evaporator unit is formed.
  • the heat pipe evaporator and the wound high voltage coil may gain mechanical stability by the casting, an effective electrical insulation may be provided between the high voltage coil and the low voltage coil, and the heat pipe evaporator may be sealed since no vapour or fluid may escape the heat pipe evaporator.
  • the casting material is selected from the group of epoxies.
  • the method further comprises the step of attaching a heat pipe condenser to the heat pipe evaporator to form a dry type transformer with a heat pipe.
  • Such a method may provide for an easy and efficient manufacturing and installation of a heat pipe to a dry type transformer, wherein the heat pipe may efficiently cool the transformer since the heat of the high voltage and low voltage coils of the transformer may be removed in an optimized way to the evaporator since at least the surface of the high voltage coil is in direct contact with the heat pipe evaporator.
  • the heat pipe condenser is detachably attached to the heat pipe evaporator via a flange or flanges such as KF-type flanges.
  • Such a detachable connection for the heat pipe condenser to the heat pipe evaporator via flanges may provide for a simple and efficient attachment and de-attachment of the heat pipe condenser to the heat pipe evaporator, for example when the heat pipe condenser needs to be exchanged.
  • the method further comprises the step of connecting the heat pipe evaporator to a heat pipe condenser via a heat pipe connector.
  • the heat pipe connector may be formed as a half-moon shaped connector and may comprise epoxy.
  • the heat pipe evaporator may be attached to the heat pipe connector such that the working fluid of the evaporator may easily exit the evaporator and move towards the connector and from there to a condenser of the heat pipe.
  • heat pipe evaporator By connecting the heat pipe evaporator to a heat pipe condenser via a heat pipe connector, different sized heat pipe evaporators and condensers may be easily connected via the interface of the heat pipe connector which may be adapted to different size connections of the heat pipe evaporator and the heat pipe condenser.
  • the step of connecting the heat pipe evaporator to the heat pipe connector comprises attaching a connector base of the condenser connected to a top gap or a bottom gap of the heat pipe evaporator, wherein the connector base comprises a connector gap matching the top and the bottom gaps, attaching a connector cap with a through-hole to the connector base, and attaching a connector insulating tube to the connector cap through the through-hole.
  • the connector consists of one single piece attached to the hollow cylinder before or after casting.
  • a silicon cap may be provided between the connector and the casting mould in order to prevent the epoxy from flowing into the cavity during casting.
  • a quick and efficient attaching of the heat pipe evaporator to a condenser may be achieved with a sealed connection of the heat pipe evaporator and the heat pipe condenser as well as an adaptive method of connecting different sized heat pipe evaporators with different sized heat pipe condensers.
  • the at least one high voltage coil comprises disk windings.
  • Such disks winding may be easily and efficiently wound onto the heat pipe evaporator. Since a high voltage coil of a transformer produces most of the heat of a transformer, the winding of the high voltage coil by winding discs to the heat pipe evaporator may advantageously provide for an efficient removing of heat from the transformer from the place where most of the heat of the transformer is produced during operation.
  • the contact area between the wound high voltage disks and the heat pipe evaporator may be enlarged, thus providing for a larger contact area and thus for a better heat removal from the high voltage coil by the heat pipe evaporator.
  • the heat pipe evaporator comprises an evaporator material similar to the high voltage coil material and with a similar thermal conductivity and thermal expansion coefficient, wherein the evaporator material is selected from the group comprising an epoxy, glass fibres, and a glass reinforced plastic or any other insulation material with similar thermal properties.
  • the thermal conductivity of the evaporator material and the coil material may range from 0,1-2,0 W/K/m.
  • the evaporator material may be similar to the low voltage coil material with respect to the thermal expansion.
  • the evaporator material is electrically insulating, and thus providing for an optimal direct dielectric insulation of the high voltage coil from the low voltage coil.
  • a dry type transformer manufactured by the method of any of the preceding aspects or exemplary embodiments of the invention is provided.
  • Such a dry type transformer may be operated with a higher power rating as dry type transformer without a heat pipe evaporator, or a small transformer may be used for a certain required power. Both options result in material and cost saving.
  • Such a dry type transformer with heat pipe evaporators may increase the transformer loading capacity, may reduce the size of a transformer, and may improve the fire safety of the dry type transformer.
  • a dry type transformer manufactured by the method of any of the preceding aspects or exemplary embodiments for a wind energy plant with a housing comprising the dry type transformer.
  • a heat pipe of the dry type transformer may comprise a condenser placed outside the housing which is cooled by wind.
  • Such a heat pipe cooled dry type transformer for a wind energy plant, the fire protection regulations of such a wind energy plant may be fulfilled, since such heat pipe cooled dry type transformer may have a high fire protection level compared to other transformers of comparable power density without such type of cooling.
  • Such a dry type transformer with a heat pipe evaporator providing for a high fire protection level may be manufactured in a small and compact size fitting in the limited space of the housing of the wind energy plant.
  • the use of a dry type transformer manufactured by the method of any of the preceding aspects or exemplary embodiments for any application in which space is limited or material cost should be reduced is provided.
  • the application may be an application selected from the group comprising a transportation means, a ship, a train, an aircraft, a vehicle, and a truck.
  • the step of attaching in the above and the below mentioned aspects and embodiments of the invention may comprise gluing, milling, smoothing with sandpaper, cleaning or other mechanical steps.
  • Fig. 1 shows a part of a dry type transformer with a limb 114, a low voltage coil 113 arranged around the limb 114, a hollow cylindrical heat pipe evaporator 101 arranged around the low voltage coil 113, and a high voltage coil 112, 120 wound onto the heat pipe evaporator 101 around a longitudinal axis 110 of the heat pipe evaporator 101.
  • the heat pipe evaporator 101 has the form of a hollow ring shaped cylinder 102 with a cavity 103 which has a radial thickness 222 which may be proportional to the amount of heat needed to be removed from the high voltage coil 112, 120 of the dry type transformer to a heat pipe.
  • the cavity 103 of the heat pipe evaporator 101 may have a radial thickness 222 of at least 2 mm.
  • the low voltage coil 113 is placed such that the heat pipe evaporator 101 is positioned between the high voltage coil 112, 120 and the low voltage coil 113.
  • the heat pipe evaporator 101 is arranged such in a thermally conducting contact with the high voltage coil 112, 120 to remove heat from the high voltage coil 112, 120 and from the low voltage coil 113, and is made of dielectric material to dielectrically insulate the high voltage coil 112, 120 from the low voltage coil 113.
  • the dry type transformer may be a dry type transformer with a voltage ranging from 1 kV - 75 kV.
  • Fig. 2 schematically shows a cross-sectional view of a high voltage coil 112, 120 wound onto a heat pipe evaporator 101 of a dry type transformer.
  • the heat pipe evaporator length 220 in a direction 107 of the rotational axis 110 of the heat pipe evaporator equals a high voltage coil length 221 in this direction 107.
  • the high voltage coil 112, 120 may comprise disk windings.
  • the cavity 103 of the heat pipe evaporator 101 has a determined radial thickness 222 of at least 2 mm which may be proportional to the amount of heat needed to be removed from the high voltage coil 112, 120 of the dry type transformer to a condenser of a heat pipe.
  • the heat pipe evaporator 101 comprises an inner concentric tube 201 with a first diameter 203 and comprises an outer concentric tube 202 with a second diameter 204 which is larger than the first diameter 203.
  • the inner concentric tube 201 features a surface structure to strengthen the heat pipe evaporator 101 and to reduce the working fluid volume of the heat pipe evaporator 101.
  • the inner concentric tube 201 may comprise spacers spaced apart from each other to create the cavity 103 of the heat pipe evaporator.
  • the high voltage coil 112, 120 is wound onto the outer concentric tube 202, wherein a low voltage coil may be arranged on the inner concentric tube 201.
  • a top gap 210 and a bottom gap 211 of the heat pipe evaporator 101 at a top end 213 and at a bottom end 214 of the heat pipe evaporator 101 may be closed by arranging a top sealing ring 215 in the top gap 210 and by arranging a bottom sealing ring 216 in the bottom gap 211.
  • the top and bottom sealing rings 215, 216 have a wedge-like cross-sectional shape to facilitate attaching or gluing the rings 215, 216 in between the two tubes 201, 202 of the heat pipe evaporator 101 which is required in order to ensure the tightness and the sealing of the heat pipe evaporator by providing a large contact area of the gaps 210, 211 with the sealing rings 215, 216.
  • the top and bottom gaps 210, 211 may have a radial distance smaller than a radial thickness 222 of the cavity 103.
  • the sealing rings 215, 216 may be omitted by providing the inner concentric tube 201 with protrusions extending radially towards the longitudinal axis 110 at the top and bottom ends 213, 214 of the heat pipe evaporator 101 with a radial length similar to the radial thickness 222 such that the heat pipe evaporator 101 may be sealed tight when the outer concentric tube 202 is attached to the inner concentric tube 201.
  • the high voltage coil 112, 120 and the heat pipe evaporator 101 are casted by an epoxy, such that a casted high voltage coil evaporator unit 230 is formed.
  • a low voltage coil which may be arranged within the inner concentric tube 201 of the heat pipe evaporator may also be casted such that a casted high voltage coil and low voltage coil evaporator unit may be formed.
  • FIG. 3 schematically shows a heat pipe evaporator 101 in form of a hollow cylinder 102 with an inner concentric tube 201 and an outer concentric tube 202 attached to the inner concentric tube 201 forming a cavity 103 between the inner concentric tube 201 and the outer concentric tube 202.
  • a top gap 210 is closed by arranging a top sealing ring 215 in the top gap 210 at a top end 213 of the heat pipe evaporator and a bottom gap (not shown, see Fig. 2 ) is closed by arranging a bottom sealing ring 216 at a bottom end 214 of the heat pipe evaporator.
  • a connector 302 may be connected to the heat pipe evaporator 101 by attaching a connector base 304 of the connector 302 to the top gap 210 of the heat pipe evaporator 101.
  • a connector cap 305 with a through-hole may be attached to the connector base 304.
  • a connector insulating tube 306 may be connected to the connector cap 305 through the through-hole (not shown, see Fig. 5 ).
  • Fig. 4 schematically shows a perspective view of an inner concentric tube 201 of the heat pipe evaporator (see Figs. 1 to 3 ) with spacers 401 spaced apart from each other by a first distance 402 in a circumferential direction 403 of the inner concentric tube 201 to create the cavity of the heat pipe evaporator, when an outer concentric tube is attached to the inner concentric tube 201.
  • Fig. 5 schematically shows a perspective view of a connector base 304 and a connector cap 305 of a connector 302 before a connection to a part of the heat pipe evaporator in form of a hollow cylinder 102 with an inner concentric tube 201 and an outer concentric tube 202 forming an upper gap 210 of a heat pipe evaporator cavity.
  • the connector base 304 may be attached to the top gap 210 of the heat pipe evaporator, wherein the connector base 304 comprises the connector gap 501 matching the top gap 210.
  • the connector base 304 may also be connected to a bottom gap of the heat pipe evaporator (not shown).
  • the connector cap 305 with a through-hole 502 may be attached to the connector base 304.
  • a connector insulating tube (not shown) may be attached to the connector cap 305 through the through-hole 502.
  • Fig. 6 schematically shows a cross-sectional view of a heat pipe evaporator 101 in form of a hollow cylinder of part of a dry type transformer with high voltage disk windings 604 of a high voltage coil wound on an outer concentric tube of the heat pipe evaporator 101.
  • the heat pipe evaporator 101 is closed at its ends at a top and a bottom end by a top sealing ring 215 and by a bottom sealing ring 216, wherein a heat pipe connector 302 is connected to the heat pipe evaporator at the top end.
  • the heat pipe evaporator 101 with thereto wound high voltage disk windings 604 is casted by a casting mould 602.
  • the casting mould 602 may be a metallic material such as steel.
  • a silicon cap 601 may be provided between the connector 302 and the casting mould 602 in order to prevent the epoxy from flowing into the hollow cylinder cavity during casting.
  • An abutment 603 or a radial space holder is arranged between the casting mould 602 and the bottom sealing ring 216 in order to squeeze the silicon cap 601 at the connector 302 at the top end of the heat pipe evaporator 101.
  • the heat pipe evaporator 101 may be arranged over a winding mandrel 606 before the winding of the high voltage coil in form of a high voltage disk 604 takes place.
  • Fig. 7 schematically shows a cross-sectional top view of the casted high voltage coil with the heat pipe evaporator of the dry type transformer according to Fig. 6 .
  • a casting mould 602 is casted to the heat pipe evaporator 101 and the thereto wound high voltage coil with the high voltage disk windings 604 to a casted high voltage coil evaporator unit 230.
  • the outer diameter 609 of the casted high voltage coil evaporator unit 230 may have a length of 700 mm, depending on the rating of the transformer.
  • the inner diameter 608 of the casted high voltage coil evaporator unit 230 may have a length of 550 mm, depending on the rating of the transformer.
  • the longitudinal axis 110 of the heat pipe evaporator 101 is arranged in the middle of the casted high voltage coil evaporator unit 230 in a direction 107.
  • the casted high voltage coil evaporator unit 230 comprises a horizontal axis 607 and a vertical axis 608 located perpendicular to each other and both located perpendicular to the longitudinal axis 110.
  • the casted mould 602 protrudes over the casted high voltage coil evaporator unit 230 at one side in the direction of the vertical axis 608.
  • Fig. 8 schematically shows a perspective view of a high voltage coil 120 of a transformer.
  • Spacers 311 are attached onto a coil surface 312 of the dry type transformer or onto a surface of a component (not shown, see component 224 of Fig. 9 ) such that the spacers 311 are spaced apart from each other.
  • the spacers 311 may be spaced apart by a first distance 313 in a circumferential direction 314 of the high voltage coil 120.
  • the spacers 311 may be attached onto the coil surface 312 in such a way that the spacers 311 are spaced apart from each other at a connection region 318 of a cavity of a heat pipe evaporator formed by the component and the coil surface 312 to be connected to a heat pipe connector by a second distance 316 in an axial direction 107 parallel to the longitudinal axis 110 of the heat pipe evaporator.
  • the spacers 311 may be attached onto the coil surface 312 in such a way that the spacers 311 are spaced apart by the second distance 316 in the axial direction 107 parallel to the longitudinal axis 110 only at the connection region 318 or along the whole longitudinal length of the coil surface 312.
  • the second distance 316 may range from 4-5 cm
  • the first distance 313 may range from 4-5 cm.
  • the spacers 311 may have a width of 8 mm - 10 mm in the circumferential direction 314.
  • the spacers 311 may not be spaced apart in the longitudinal direction 107 but form longitudinal stripes according to an embodiment of the invention.
  • the component may be attached onto the spacers 311 or the component with thereto attached spacers 311 may be attached onto the coil surface 312 to create a cavity (not shown) adapted to act as the heat pipe evaporator with a first wall formed by the coil surface 312 and a second wall formed by the component such that the evaporator is in direct thermal contact with the coil surface 312.
  • the term attaching may be designated as gluing.
  • the spacers 311 may be epoxy stripes ensuring the formation of a hollow volume after closing the evaporator.
  • the component 224 may be a rigid epoxy foil attached to the spacers 311 to create a rigid inner wall of the evaporator which is able to withstand the evacuation of the system before operation.
  • the outer wall of the evaporator may be formed by the inner border of the high voltage coil 120 providing for an optimal thermal contact since there is no additional material placed between the inside of the evaporator and the high voltage coil 120.
  • the cavity length in a direction 107 of the longitudinal axis of the coil may equal a coil length in the direction of the longitudinal axis 107.
  • Fig. 9 schematically shows the high voltage coil 120 for a dry type transformer of Fig. 12 wherein the component 224 is already attached to the spacers of the coil surface, and a lower gap and an upper gap between the component 224 and a coil surface is closed with pre-impregnated fibres (PRE-PREG) which may comprise layers of epoxy soaked glass fibres.
  • the pre-impregnated fibres may take the form of a weave or may be unidirectional and contain an amount of matrix material used to bond them together and to other components during manufacture.
  • the component 224 may be enforced by adding further PRE-PREG to the component 224 such that the component 224 gains mechanical stability and may be sealed by PRE-PREG to hinder the escape of the working fluid of the heat pipe evaporator.
  • the heat pipe evaporator may be connected to a heat pipe connector 302 with an insulating tube 306 leading to a heat pipe condenser where a vapour of the evaporator working fluid may be condensed.
  • a heat resistant sealing material such as araldite may be added to the component and the closed upper and lower gaps for further sealing the heat pipe evaporator.
  • a sealed evaporator may be provided enabling an optimal heat exchange from the coil of the transformer within the heat pipes since no liquid or vapour may escape the heat pipe evaporator within the heat pipe cycle.
  • the heat pipe evaporator may be located between the high voltage coil and a low voltage coil. The evaporator may be exposed to thermal radiation from the low voltage coil, and may move heat from the high voltage coil and via the component 224 from the low voltage coil of the transformer to the heat pipe.
  • a method of manufacturing a dry type transformer comprising a heat pipe evaporator, with the steps of attaching spacers onto a coil surface of the dry type transformer or onto a surface of a component such that the spacers are spaced apart from each other, attaching the component onto the spacers or attaching the component with thereto attached spacers onto the coil surface to create a cavity adapted to act as the heat pipe evaporator with a first wall formed by the coil surface and a second wall formed by the component such that the evaporator is in direct thermal contact with the coil surface.
  • the method may further comprise the step of closing a lower gap and an upper gap between the component and the coil surface with pre-impregnated fibres.
  • the method may further comprise enforcing the component by adding pre-impregnated fibres to the component, and according to a further embodiment of the invention the method may comprise adding a heat resistant sealing material to the component and the closed upper and lower gaps for sealing the heat pipe evaporator.
  • the method may comprise the step of attaching a heat pipe condenser to the heat pipe evaporator forming a heat pipe. The step of attaching may comprise connecting the heat pipe evaporator, and in particular the cavity of the heat pipe evaporator, to a heat pipe connector, and connecting the heat pipe connector to the heat pipe condenser.
  • Fig. 10 schematically shows a flow-chart of a method 800 of manufacturing a dry type transformer with a heat pipe evaporator, at least one high voltage coil, at least one low voltage coil, and a core with at least one limb, the method comprising: providing 801 a hollow cylindrical heat pipe evaporator, winding 802 a high voltage coil onto the heat pipe evaporator around a longitudinal axis of the heat pipe evaporator, placing 803 a low voltage coil such that the heat pipe evaporator is positioned between the high voltage coil and the low voltage coil, wherein the heat pipe evaporator is designed to remove heat from the high voltage coil and from the low voltage coil, and is designed to dielectrically insulate the high voltage coil from the low voltage coil.
  • the method further comprises the step of arranging 804 the heat pipe evaporator over a winding mandrel before the winding of the high voltage coil, arranging 805 the low voltage coil on an inner concentric tube of the heat pipe evaporator, wherein the high voltage coil is wound to an outer concentric tube of the evaporator, and arranging 806 the low voltage coil and the high voltage coil around the at least one limb.
  • a further step of the method is pre-fabricating 807 the heat pipe evaporator with the steps of manufacturing an inner concentric tube with spacers which are attached to the inner concentric tube and spaced apart from each other, manufacturing an outer concentric tube, and attaching the outer concentric tube onto the spacers of the inner concentric tube such that a cavity is provided between the outer concentric tube and the inner concentric tube, the cavity acting as the heat pipe evaporator.
  • a further step of the method is closing 808 a top gap and a bottom gap of the heat pipe evaporator at a top end and at a bottom end of the heat pipe evaporator by arranging a top sealing ring in the top gap and by arranging a bottom sealing ring in the bottom gap.
  • step of adding 809 a reinforcement material to the wound high voltage coil is performed. Further steps of the method are casting 810 the high voltage coil and the heat pipe evaporator such that a casted high voltage coil evaporate unit is formed, attaching 811 a heat pipe condenser to the heat pipe evaporator to form a dry type transformer with a heat pipe, and connecting 812 the heat pipe evaporator to a heat pipe condenser via a heat pipe connector.
  • Fig. 11 schematically shows a flow-chart of a method of connecting 812 the heat pipe evaporator to the heat pipe connector, comprising the steps of attaching 901 a connector base of the connector to a top gap or a bottom gap of the heat pipe evaporator, wherein the connector base comprises a connector gap matching the top and the bottom gaps, attaching 902 a connector cap with a through-hole to the connector base, and attaching 903 a connector insulating tube to the connector cap through the through-hole.
  • Fig. 12 schematically shows a dry type transformer 1000 with three coils 120, the dry type transformer 1000 comprising a heat pipe evaporator and manufactured by the method of Fig. 10 or by the method of any of the before-mentioned aspects and embodiments of the invention.
  • a condenser which may be mounted on top of the transformer is not shown.
  • Fig. 13 schematically shows a cross-sectional view of a wind energy plant 1100 with a housing 1101 comprising the dry type transformer 1000 of Fig. 12 , wherein the heat pipe of the transformer 1000 comprises a condenser 1102 which is placed outside the housing (1101) and cooled by wind.
  • Fig. 14 schematically shows a ship 1200 having the dry type transformer 1000 of Fig. 12 , wherein a heat pipe of the transformer 1000 comprises a condenser 1102 which is thermally coupled to a wall or a floor of the ship 1200.
  • Fig. 15 schematically shows a train 1300 having the dry type transformer 1000 of Fig. 12 , wherein a heat pipe of the transformer 1000 comprises a condenser 1102 which is arranged at the train 1300 such that a cooling of the condenser 1102 by train airflow is provided.

Landscapes

  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Coils Of Transformers For General Uses (AREA)
EP10194530A 2010-12-10 2010-12-10 Trockenwandler mit Hitzerohr in der Hochspannungswickelung Withdrawn EP2463870A1 (de)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP10194530A EP2463870A1 (de) 2010-12-10 2010-12-10 Trockenwandler mit Hitzerohr in der Hochspannungswickelung

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
EP10194530A EP2463870A1 (de) 2010-12-10 2010-12-10 Trockenwandler mit Hitzerohr in der Hochspannungswickelung

Publications (1)

Publication Number Publication Date
EP2463870A1 true EP2463870A1 (de) 2012-06-13

Family

ID=43875320

Family Applications (1)

Application Number Title Priority Date Filing Date
EP10194530A Withdrawn EP2463870A1 (de) 2010-12-10 2010-12-10 Trockenwandler mit Hitzerohr in der Hochspannungswickelung

Country Status (1)

Country Link
EP (1) EP2463870A1 (de)

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2479764B1 (de) * 2011-01-21 2014-04-30 Hitachi Industrial Equipment Systems Co., Ltd. Harzgeformte Spule und geformter Transformator damit
US8893513B2 (en) 2012-05-07 2014-11-25 Phononic Device, Inc. Thermoelectric heat exchanger component including protective heat spreading lid and optimal thermal interface resistance
US8991194B2 (en) 2012-05-07 2015-03-31 Phononic Devices, Inc. Parallel thermoelectric heat exchange systems
WO2014120429A3 (en) * 2013-01-31 2015-10-29 APR Energy, LLC Scalable portable modular power plant
US9593871B2 (en) 2014-07-21 2017-03-14 Phononic Devices, Inc. Systems and methods for operating a thermoelectric module to increase efficiency
CN109539751A (zh) * 2018-12-26 2019-03-29 江苏宏宝电力有限公司 一种变压器套管除湿装置及使用方法
US10458683B2 (en) 2014-07-21 2019-10-29 Phononic, Inc. Systems and methods for mitigating heat rejection limitations of a thermoelectric module
WO2020051077A1 (en) * 2018-09-07 2020-03-12 Abb Schweiz Ag Leakage reactance plate for power transformer

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1488347A1 (de) * 1963-06-28 1969-07-17 Const Electr & Mecaniques Soc Hochleistungs- und Hochspannungstransformator
US6368530B1 (en) * 1999-12-16 2002-04-09 Square D Company Method of forming cooling ducts in cast resin coils
DE60209574T2 (de) 2001-12-21 2006-08-24 Abb Technology Ag Kühlkanal für in kunstharz vergossene transformatorspule
WO2010139597A1 (de) * 2009-06-05 2010-12-09 Abb Technology Ag Transformatorspule und transformator mit passiver kühlung

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1488347A1 (de) * 1963-06-28 1969-07-17 Const Electr & Mecaniques Soc Hochleistungs- und Hochspannungstransformator
US6368530B1 (en) * 1999-12-16 2002-04-09 Square D Company Method of forming cooling ducts in cast resin coils
DE60209574T2 (de) 2001-12-21 2006-08-24 Abb Technology Ag Kühlkanal für in kunstharz vergossene transformatorspule
WO2010139597A1 (de) * 2009-06-05 2010-12-09 Abb Technology Ag Transformatorspule und transformator mit passiver kühlung

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2479764B1 (de) * 2011-01-21 2014-04-30 Hitachi Industrial Equipment Systems Co., Ltd. Harzgeformte Spule und geformter Transformator damit
US9310111B2 (en) 2012-05-07 2016-04-12 Phononic Devices, Inc. Systems and methods to mitigate heat leak back in a thermoelectric refrigeration system
US10012417B2 (en) 2012-05-07 2018-07-03 Phononic, Inc. Thermoelectric refrigeration system control scheme for high efficiency performance
US9103572B2 (en) 2012-05-07 2015-08-11 Phononic Devices, Inc. Physically separated hot side and cold side heat sinks in a thermoelectric refrigeration system
US9234682B2 (en) 2012-05-07 2016-01-12 Phononic Devices, Inc. Two-phase heat exchanger mounting
US8893513B2 (en) 2012-05-07 2014-11-25 Phononic Device, Inc. Thermoelectric heat exchanger component including protective heat spreading lid and optimal thermal interface resistance
US9341394B2 (en) 2012-05-07 2016-05-17 Phononic Devices, Inc. Thermoelectric heat exchange system comprising cascaded cold side heat sinks
US8991194B2 (en) 2012-05-07 2015-03-31 Phononic Devices, Inc. Parallel thermoelectric heat exchange systems
WO2014120429A3 (en) * 2013-01-31 2015-10-29 APR Energy, LLC Scalable portable modular power plant
US9593871B2 (en) 2014-07-21 2017-03-14 Phononic Devices, Inc. Systems and methods for operating a thermoelectric module to increase efficiency
US10458683B2 (en) 2014-07-21 2019-10-29 Phononic, Inc. Systems and methods for mitigating heat rejection limitations of a thermoelectric module
WO2020051077A1 (en) * 2018-09-07 2020-03-12 Abb Schweiz Ag Leakage reactance plate for power transformer
US11139109B2 (en) 2018-09-07 2021-10-05 Abb Power Grids Switzerland Ag Leakage reactance plate for power transformer
CN109539751A (zh) * 2018-12-26 2019-03-29 江苏宏宝电力有限公司 一种变压器套管除湿装置及使用方法
CN109539751B (zh) * 2018-12-26 2023-05-30 江苏宏宝电力有限公司 一种变压器套管除湿装置及使用方法

Similar Documents

Publication Publication Date Title
EP2463870A1 (de) Trockenwandler mit Hitzerohr in der Hochspannungswickelung
US8742876B2 (en) Transformer coil and transformer with passive cooling
US10734867B2 (en) High thermal conductivity stator component for vehicle motor based on 3D phase change heat pipe technology
WO2011029488A1 (en) Transformer comprising a heat pipe
US20170063200A1 (en) Fluid-cooled stator assemblies having multilayer and multifunctional tubing
US11683919B2 (en) Conformal heat pipe assemblies
US5656984A (en) Solid insulation transformer
CN104838457A (zh) 用于传导式冷却的、有空隙的、高透磁率的磁性组件的线轴设计
CN104995699A (zh) 变压器组件
US11606017B2 (en) Wind turbine having superconducting generator and armature for use in the superconducting generator
CN111354543A (zh) 磁性组件及电源模块
US9531242B2 (en) Apparatuses and methods for cooling electric machines
US6324851B1 (en) Cryostat for use with a superconducting transformer
KR101114995B1 (ko) 열배출수단을 이용한 콤팩트 변압기
EP2333798B1 (de) Wärmetauschersystem für Trockentransformatoren
KR101554149B1 (ko) 몰드 변압기용 냉각 시스템
CN110556950B (zh) 转子内冷式脉冲发电机
FI123733B (fi) Nestejäähdytyksellä varustettu induktiivinen komponentti ja menetelmä induktiivisen komponentin valmistamiseksi
CN106252033A (zh) 一种具有新型散热结构的大功率高频变压器
KR20120051889A (ko) 열배출수단이 구비된 콤팩트 변압기 및 이의 제조방법
JPH1012458A (ja) 樹脂注型コイル及びその製造方法
CN110491640B (zh) 一种加快油浸自冷变压器油冷却的方法
CN214479897U (zh) 一种电机定子插管冷却装置
CN210927358U (zh) 一种直流耐压的低压屏蔽水内冷发电机
CN116111748B (zh) 一种强化型同步散热定子结构

Legal Events

Date Code Title Description
PUAI Public reference made under article 153(3) epc to a published international application that has entered the european phase

Free format text: ORIGINAL CODE: 0009012

AK Designated contracting states

Kind code of ref document: A1

Designated state(s): AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

AX Request for extension of the european patent

Extension state: BA ME

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: THE APPLICATION IS DEEMED TO BE WITHDRAWN

18D Application deemed to be withdrawn

Effective date: 20121214