阅读说明：本技术 变压器、冷却系统及风力发电机组 (Transformer, cooling system and wind generating set ) 是由 付伟 艾斯卡尔 张雅琼 盛国东 于 2020-05-25 设计创作，主要内容包括：本发明涉及一种变压器、冷却系统及风力发电机组,变压器包括：铁芯,整体呈柱状体；线圈组件,环绕铁芯的外缘设置并与铁芯配合；相变导热管,插接于线圈组件,相变导热管包括具有封闭腔的管壳以及设置于封闭腔内的冷却液；在铁芯的高度方向,相变导热管包括相对设置的蒸发段以及冷凝段,冷却液位于蒸发段,冷凝段在高度方向凸出于线圈组件；相变导热管被配置为通过蒸发段与线圈组件热交换,以使冷却液汽化运行至冷凝段,并在冷凝段处液化后返回至蒸发段,以循环冷却线圈组件。本发明实施例提供的变压器利用冷却液的相变原理实现冷却,冷却散热功耗小且成本低。(The invention relates to a transformer, a cooling system and a wind generating set, wherein the transformer comprises: the iron core is integrally cylindrical; the coil assembly is arranged around the outer edge of the iron core and matched with the iron core; the phase-change heat conduction pipe is inserted in the coil assembly and comprises a pipe shell with a closed cavity and cooling liquid arranged in the closed cavity; in the height direction of the iron core, the phase change heat conduction pipe comprises an evaporation section and a condensation section which are oppositely arranged, the cooling liquid is positioned in the evaporation section, and the condensation section protrudes out of the coil assembly in the height direction; the phase change heat conduction pipe is configured to exchange heat with the coil assembly through the evaporation section, so that the cooling liquid is vaporized and runs to the condensation section, and returns to the evaporation section after being liquefied at the condensation section, and the coil assembly is cooled circularly. The transformer provided by the embodiment of the invention realizes cooling by utilizing the phase change principle of the cooling liquid, and has the advantages of low cooling and heat dissipation power consumption and low cost.)

1. A transformer (100), comprising:

an iron core (10) integrally formed in a cylindrical shape;

the coil assembly (20) is arranged around the outer edge of the iron core (10) and matched with the iron core (10);

the phase-change heat pipe (30) is inserted into the coil assembly (20), and the phase-change heat pipe (30) comprises a pipe shell (31) with a closed cavity (311) and cooling liquid (32) arranged in the closed cavity (311); in the height direction (X) of the iron core (10), the phase change heat pipe (30) comprises an evaporation section (30a) and a condensation section (30b) which are oppositely arranged, the cooling liquid (32) is located in the evaporation section (30a), and the condensation section (30b) protrudes out of the coil assembly (20) in the height direction (X);

the phase change heat pipe (30) is configured to exchange heat with the coil assembly (20) through the evaporation section (30a) to make the cooling liquid (32) run to the condensation section (30b) in a vaporized manner, and return to the evaporation section (30a) after being liquefied at the condensation section (30b) to circularly cool the coil assembly (20).

2. The transformer (100) of claim 1, wherein the coil assembly (20) comprises a first coil (21) and a second coil (22) respectively disposed around the core (10), the first coil (21) being located between the core (10) and the second coil (22), the first coil (21) and the second coil (22) being spaced apart from each other and forming a first annular air duct (23), the phase change heat pipe (30) being disposed within the first annular air duct (23).

3. The transformer (100) according to claim 1, wherein the coil assembly (20) comprises a first coil (21) and a second coil (22) respectively disposed around the core (10), the number of the first coils (21) is two or more, and the two or more first coils (21) are each located between the core (10) and the second coil (22);

and a second annular air duct (24) is formed between every two adjacent first coils (21), and the phase change heat conduction pipe (30) is arranged in at least one second annular air duct (24).

4. Transformer (100) according to claim 2 or 3, wherein the phase change heat conducting tube (30) is inserted in the second coil (22).

5. The transformer (100) according to claim 2 or 3, wherein the first coil (21) is a low voltage coil and the second coil (22) is a high voltage coil.

6. The transformer (100) of claim 1, wherein the phase change heat conducting pipe (30) is plural in number, and at least a part of the number of the phase change heat conducting pipes (30) are spaced apart from each other along an outer edge of the core (10).

7. The transformer (100) according to claim 6, wherein the transformer (100) further comprises a protective housing (40), the core (10) and the coil assembly (20) are located in the protective housing (40), the protective housing (40) has an upper cover (41), the upper cover (41) is provided with a number of perforations (42) which is not less than the number of the phase change heat pipes (30), each of the phase change heat pipes (30) is in clearance fit with the perforations (42) and the condensation section (30b) protrudes from the upper cover (41).

8. The transformer (100) according to claim 1, wherein the phase-change heat-conducting pipe (30) further comprises a wick (33), the wick (33) is disposed in the closed cavity (311) and attached to the inner wall of the case (31), and the wick (33) is made of a capillary porous material.

9. The transformer (100) of claim 8, wherein the wick (33) comprises two or more mesh layers (331) sequentially stacked along a direction away from the inner wall, wherein the mesh number of the mesh layers (331) disposed near the inner wall is smaller than the mesh number of the mesh layers (331) disposed away from the inner wall.

10. The transformer (100) according to claim 1, wherein the number of the iron cores (10) is more than two and the iron cores are arranged at intervals, each iron core (10) is provided with the coil assembly (20), and the phase change heat conducting pipe (30) is inserted into at least one coil assembly (20).

11. A cooling system for a transformer (100) according to any of claims 1 to 10, characterized in that the cooling system comprises:

a heat sink (200) having a fitting portion (210), the fitting portion (210) being for contacting the condensation section (30b) of the phase-change heat conductive pipe (30);

a cooling part (300) disposed opposite to the radiator (200) and supplying a cooling medium to the radiator (200), the cooling medium flowing through the radiator (200) and exchanging heat with the radiator (200) to liquefy the coolant (32) vaporized in the condensation section (30b) and to flow back to the evaporation section (30 a).

12. The cooling system according to claim 11, wherein the heat sink (200) comprises a plurality of heat dissipating fins (210a) spaced apart from each other, adjacent two of the heat dissipating fins (210a) together form the fitting portion (210), and the condensing section (30b) of the phase-change heat conductive pipe (30) is sandwiched between adjacent two of the heat dissipating fins (210 a);

and/or the cooling component (300) comprises a fan, the fan comprises an air inlet (310) and an air outlet (320), the air inlet (310) is provided with a filtering component (400), and the air outlet (320) is arranged facing the radiator (200).

13. A wind turbine generator set, comprising:

the tower drum (500) comprises a drum wall (510) and an accommodating cavity (520) formed by enclosing the drum wall (510), wherein an opening (530) communicated with the accommodating cavity (520) is formed in the drum wall (510);

the transformer (100) of any one of claims 1 to 10, wherein the transformer (100) is disposed in the accommodating cavity (520) and the phase change heat conducting pipe (30) extends along an axial direction of the tower (500); and

the cooling system according to claim 11 or 12, wherein a radiator (200) of the cooling system is arranged in the accommodating chamber (520), the cooling component (300) is located outside the accommodating chamber (520) and connected with the cylinder wall (510), and the cooling medium provided by the cooling component (300) flows to the radiator (200) through the opening (530) and exchanges heat with the radiator (200).

Technical Field

The invention relates to the technical field of wind power, in particular to a transformer, a cooling system and a wind generating set.

Background

A Transformer (Transformer) is a device that changes an ac voltage by using the principle of electromagnetic induction, and has the main functions of: voltage transformation, current transformation, impedance transformation, isolation, voltage stabilization (magnetic saturation transformer), and the like, and the application is very wide, especially in the technical field of wind power. For the transformer of the wind generating set on the main loop, the transformer carries the transmission task of electric power, so heat is necessarily generated in the operation process. If the heat generated is not well transferred or the heat balance control is not well controlled, it inevitably results in aging and damage of the insulation, and even causes fire or damage, and thus, is very important for cooling the transformer.

The existing transformer is unreasonable in structural design, so that the cooling mode of the existing transformer is that the cooling fan in the transformer cabinet body drives the heat of a transformer coil to blow through an air-water cooling plate, then the heat is led to a water-air radiator outside a tower (or outside an engine room) through a water pump and a water channel, the heat carried by cooling water is dissipated into the air through water-air cooling, and the cooling water returns to the inside of a tower barrel after being cooled, and circulates according to the above, and finally the heat balance target of the transformer is achieved.

The water cooling system comprises a water cooling host, an external radiator, a sensor, a control system, a connecting pipeline and the like. The water-cooling main machine keeps constant pressure and flow rate of a cooling medium by means of the driving action of the water pump, so that the cooling medium continuously flows through the cooled equipment, transfers heat emitted by the cooled equipment to an external radiator and exchanges heat with the atmosphere, emits the heat into air, cools down after flowing through the external radiator, and flows into the cooled equipment again under the driving action of the water pump to start next closed cycle. If the transformer is an oil-immersed transformer, the cooling principle of the transformer is basically similar to that of a dry-type transformer, and the only difference is that: the heat circulation in the transformer is realized by an oil pump. However, the transformer has a large cooling power consumption and a high cost because of the presence of the circulating pump and other devices, regardless of whether the air-water-air cooling scheme or the oil-water-air cooling scheme is used.

Therefore, a new transformer, a cooling system and a wind turbine generator set are needed.

Disclosure of Invention

The embodiment of the invention provides a transformer, a cooling system and a wind generating set.

In one aspect, an embodiment of the present invention provides a transformer, including: the iron core is integrally cylindrical; the coil assembly is arranged around the outer edge of the iron core and matched with the iron core; the phase-change heat conduction pipe is inserted in the coil assembly and comprises a pipe shell with a closed cavity and cooling liquid arranged in the closed cavity; in the height direction of the iron core, the phase change heat conduction pipe comprises an evaporation section and a condensation section which are oppositely arranged, the cooling liquid is positioned in the evaporation section, and the condensation section protrudes out of the coil assembly in the height direction; the phase change heat conduction pipe is configured to exchange heat with the coil assembly through the evaporation section, so that the cooling liquid is vaporized and runs to the condensation section, and returns to the evaporation section after being liquefied at the condensation section, and the coil assembly is cooled circularly.

According to an aspect of the embodiment of the present invention, the coil assembly includes a first coil and a second coil respectively disposed around the core, the first coil is located between the core and the second coil, the first coil and the second coil are spaced from each other and form a first annular air duct, and a phase change heat pipe is disposed in the first annular air duct.

According to one aspect of the embodiment of the invention, the coil assembly comprises a first coil and a second coil which are respectively arranged around the iron core, the number of the first coils is more than two, and the more than two first coils are positioned between the iron core and the second coil; a second annular air duct is formed between every two adjacent first coils, and a phase change heat conduction pipe is arranged in at least one second annular air duct.

According to one aspect of an embodiment of the invention, a phase change heat pipe is inserted into the second coil.

According to an aspect of an embodiment of the present invention, the first coil is a low voltage coil and the second coil is a high voltage coil.

According to an aspect of the embodiment of the present invention, the phase change heat conducting pipe is provided in a plurality, and at least a part of the phase change heat conducting pipes are spaced apart from each other along an outer edge of the core.

According to one aspect of the embodiment of the invention, the transformer further comprises a protective shell, the iron core and the coil assembly are located in the protective shell, the protective shell is provided with an upper cover, the upper cover is provided with perforations, the number of the perforations is not less than the number of the phase change heat conduction pipes, each phase change heat conduction pipe is in clearance fit with the perforations, and the condensation section protrudes out of the upper cover.

According to an aspect of the embodiment of the present invention, the phase-change heat conduction pipe further includes a wick, the wick is disposed in the closed cavity and attached to an inner wall of the pipe shell, and the wick is made of a capillary porous material.

According to one aspect of the embodiment of the invention, the liquid absorption core comprises more than two layers of net layers which are sequentially stacked along the position far away from the inner wall, wherein the mesh number of the net layers close to the inner wall is smaller than that of the net layers far away from the inner wall.

According to an aspect of the embodiment of the present invention, the number of the iron cores is two or more, the iron cores are arranged at intervals, each iron core is provided with a coil assembly, and a phase change heat pipe is inserted into at least one coil assembly.

In another aspect, a cooling system is provided according to an embodiment of the present invention, and is used for the transformer, where the cooling system includes: the radiator is provided with a matching part which is used for being in contact with the condensation section of the phase change heat conduction pipe; and the cooling part is arranged opposite to the radiator and provides a cooling medium for the radiator, and the cooling medium flows through the radiator and exchanges heat with the radiator so as to liquefy the cooling liquid vaporized in the condensation section and return the cooling liquid to the evaporation section.

According to another aspect of the embodiment of the invention, the heat sink comprises a plurality of heat dissipation fins distributed at intervals, two adjacent heat dissipation fins jointly form a matching part, and the condensation section of the phase change heat conduction pipe is clamped between the two adjacent heat dissipation fins;

and/or, the cooling part comprises a fan, the fan comprises an air inlet and an air outlet, the air inlet is provided with a filtering part, and the air outlet is arranged facing the radiator.

In another aspect, an embodiment of the present invention provides a wind turbine generator system, including: the tower drum comprises a drum wall and an accommodating cavity formed by enclosing the drum wall, wherein an opening communicated with the accommodating cavity is formed in the drum wall; in the transformer, the transformer is arranged in the accommodating cavity, and the phase change heat conducting pipe extends along the axial direction of the tower barrel; and the radiator of the cooling system is arranged in the accommodating cavity, the cooling part is positioned outside the accommodating cavity and connected with the cylinder wall, and the cooling medium provided by the cooling part flows to the radiator through the opening and exchanges heat with the radiator.

According to the transformer, the cooling system and the wind generating set provided by the embodiment of the invention, the transformer comprises an iron core, a coil assembly and a phase change heat pipe, the coil assembly is arranged around the iron core, the phase change heat pipe comprises a pipe shell with a closed cavity and cooling liquid arranged in the closed cavity, in addition, in the height direction of the iron core, the phase change heat pipe comprises an evaporation section and a condensation section which are oppositely arranged, the cooling liquid is arranged at the evaporation section, the condensation section protrudes out of the coil assembly in the height direction, the phase change heat pipe is inserted and arranged in the coil assembly, so that the phase change heat pipe can exchange heat with the coil assembly through the evaporation section, the cooling liquid is vaporized and runs to the condensation section, only a cooling medium matched with the condensation section is arranged to liquefy the vaporized cooling liquid and then returns to the evaporation section, the coil assembly can be circularly cooled, and the cooling heat dissipation requirement on the interior of the transformer is realized by utilizing the phase change principle of the cooling liquid in the phase change cooling pipe, the flowing of the cooling liquid is realized without devices such as a circulating pump and the like, so that the cooling whole power consumption of the transformer is low and the cost is low.

Drawings

Features, advantages and technical effects of exemplary embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of the cooling of an exemplary prior art transformer;

FIG. 2 is an isometric view of a transformer of one embodiment of the present invention;

FIG. 3 is a front view of a transformer according to one embodiment of the present invention;

FIG. 4 is a partial cross-sectional view of a transformer according to one embodiment of the present invention;

fig. 5 is a partial cross-sectional view of a transformer according to another embodiment of the present invention;

fig. 6 is a partial cross-sectional view of a transformer of yet another embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a phase change heat pipe according to an embodiment of the invention;

FIG. 8 is an enlarged view at A of FIG. 7;

FIG. 9 is a schematic diagram of the cooling system and transformer of one embodiment of the present invention;

FIG. 10 is a partial schematic diagram of a cooling system in accordance with an embodiment of the present invention in conjunction with a transformer;

FIG. 11 is a schematic structural view of a wind turbine generator set according to an embodiment of the present invention;

fig. 12 is a partial sectional structural schematic view of a wind turbine generator system according to an embodiment of the present invention.

Wherein:

100-a transformer;

10-an iron core;

20-a coil assembly; 21-a first coil; 22-a second coil; 23-a first annular air duct; 24-a second annular air duct;

30-phase change heat conducting pipe; 31-a tube shell; 311-a closed cavity; 32-cooling liquid; 33-a wick; 331-mesh layer; 30 a-an evaporation section; 30 b-a condensation section;

40-a protective shell; 41-upper cover; 42-punching;

200-a heat sink; 210-a mating portion; 210 a-heat sink fins;

300-a cooling member; 310-an air inlet; 320-air outlet;

400-a filter element;

500-tower drum; 510-a cylinder wall; 520-a containment chamber; 530-opening;

600-a nacelle;

700-a generator;

800-impeller; 810-a hub; 820-blades;

x-height direction.

In the drawings, like parts are provided with like reference numerals. The figures are not drawn to scale.

Detailed Description

Features and exemplary embodiments of various aspects of the present invention will be described in detail below. In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced without some of these specific details. The following description of the embodiments is merely intended to provide a better understanding of the present invention by illustrating examples of the present invention. In the drawings and the following description, at least some well-known structures and techniques have not been shown in detail in order to avoid unnecessarily obscuring the present invention; also, the dimensions of some of the structures may be exaggerated for clarity. Furthermore, the described features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

The following description is given with the directional terms as they are shown in the drawings, and is not intended to limit the specific structure of the transformer, the cooling system, and the wind turbine generator system of the present invention. In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as either a fixed connection, a removable connection, or an integral connection; can be directly connected or indirectly connected. The specific meaning of the above terms in the present invention can be understood as appropriate to those of ordinary skill in the art.

Referring to fig. 1, in a wind turbine generator system in the prior art, a ventilated cavity is disposed inside a transformer 1, the transformer 1 is mostly placed in a closed housing 2, and an internal cooler 3, an external cooler 4, a control device 5, a circulating pump 6, an airflow guide plate 7 and an airflow port 8 are correspondingly disposed, and the control device 5 is used for controlling the internal cooler 3, the external cooler 4 and a cooling water pump 6.

The working principle is as follows: the heat that transformer 1 inside loss itself produced upwards moves, has condenser tube's intercooler 3 through on the closed casing 2 and cools off hot-blast, and the cooling liquid can rise owing to absorbed heat temperature, passes to external cooler 4 through the condenser tube under the effect of cooling water pump 6 and cools off the coolant liquid, and the heat that transformer 1 produced just is taken to the outside through whole circulation system like this. Cooled air is blown into the bottom of the transformer 1 by a fan through the air flow port 8 and the air flow guide plate 7, so that a set of heat exchange process between the internal cooler 3 and the external cooler 4 is completed, the transformer 1 can be cooled, but due to structural limitation of the transformer 1, components such as the cooling water pump 6, the internal cooler 3 and the external cooler 4 need to be configured during cooling, power consumption is high, and cost is high.

Based on the above, the embodiment of the invention provides a novel transformer, a cooling system and a wind generating set, wherein the transformer can be cooled with low power consumption and low cost on the basis of meeting the self heat dissipation requirement. For better understanding of the present invention, a transformer, a cooling system and a wind turbine generator set according to embodiments of the present invention are described below with reference to fig. 2 to 12.

Referring to fig. 2 to 7, an embodiment of a transformer 100 includes an iron core 10, a coil assembly 20, and a phase change heat pipe 30, wherein the iron core 10 is a cylindrical body. The coil assembly 20 is disposed around the outer periphery of the core 10 and is engaged with the core 10. The phase change heat pipe 30 is inserted into the coil assembly 20, and the phase change heat pipe 30 includes a pipe shell 31 having a closed cavity 311 and a cooling liquid 32 disposed in the closed cavity 311. In the height direction X of the iron core 10, the phase change heat pipe 30 includes an evaporation section 30a and a condensation section 30b, which are disposed opposite to each other, the cooling liquid 32 is located in the evaporation section 30a, and the condensation section 30b protrudes from the coil assembly 20 in the height direction X. The phase change heat conductive pipe 30 is configured to exchange heat with the coil assembly 20 through the evaporation section 30a, to make the cooling liquid 32 run to the condensation section 30b in a vaporized state, and return to the evaporation section 30a after being liquefied at the condensation section 30b, to circulate and cool the coil assembly 20.

In the transformer 100 according to the embodiment of the present invention, when the coil assembly 20 is in operation, the phase-change heat pipe 30 is inserted into the coil assembly 20, so that heat generated by the coil assembly 20 can be exchanged with the phase-change heat pipe 30, and when the phase-change heat pipe 30 is heated, the cooling liquid 32 in the evaporation section 30a is vaporized and flows along the closed cavity 311 to the condensation section 30b, so that the cooling liquid can be liquefied into liquid drops after the condensation section 30b exchanges heat with self-heating air or other cooling media to reduce temperature. Under the action of gravity, the accumulated liquid drops flow back to the evaporation section 30a along the inner wall of the tube shell 31 of the phase change heat conduction tube 30 to exchange heat with the coil assembly 20 again, so as to cool the coil assembly 20. So circulate, utilize the phase transition principle of coolant liquid 32 in the phase transition heat pipe 30 to realize the cooling to transformer 100 internal components like coil pack 20, only need natural wind or simple cooling medium, need not to set up devices such as circulating pump simultaneously and can satisfy transformer 100's cooling requirement, the cooling of this kind of structural style's transformer 100 easily self, and the whole consumption of cooling process is little and with low costs.

With continued reference to fig. 4, in some alternative embodiments, the above embodiments provide a transformer 100, wherein the coil assembly 20 of the transformer 100 may include a first coil 21 and a second coil 22 respectively disposed around the core 10, the first coil 21 is disposed between the core 10 and the second coil 22, the first coil 21 and the second coil 22 are spaced apart from each other and form a first annular air duct 23, a phase change heat pipe 30 is disposed in the first annular air duct 23, since the transformer 100 can exchange ac voltage, current, impedance, and the like during operation, the first coil 21 and the second coil 22 are both easy to generate heat, the first annular air duct 23 is formed by disposing the first coil 21 and the second coil 22 at a distance from each other, can be cooled by natural wind, and can provide an installation space, a phase change heat pipe 30 may be disposed in the first annular air duct 23, and the phase change heat pipe 30 may be disposed in the first annular air duct 23 to simultaneously achieve cooling of the first coil 21 and the second coil 22 by utilizing a phase change characteristic of a cooling liquid 32 in the phase change heat pipe 30 So as to ensure that the transformer 100 can work in a suitable temperature environment, and thus has higher safety performance and longer service life.

Alternatively, the phase change heat pipe 30 located in the first annular air duct 23 may be fixed by the clamping force of the first coil 21 and the second coil 22, and of course, in some examples, the winding of the first coil 21 or the winding of the second coil 22 may be partially wound around the outer peripheral wall of the phase change heat pipe 30, and the position limitation of the phase change heat pipe 30 may also be satisfied.

As an alternative embodiment, the number of the phase change heat conducting pipes 30 may be plural, and at least a part of the number of the phase change heat conducting pipes 30 are spaced from each other along the outer edge of the iron core 10. In an alternative embodiment, the number of the phase change heat pipes 30 in the first annular air duct 23 may be multiple, and the multiple phase change heat pipes 30 may be arranged at intervals in the first annular air duct 23, so that the cooling effect on the first coil 21 and the second coil 22 can be optimized. Optionally, the plurality of phase change heat conducting pipes 30 are spaced and uniformly distributed in the first annular air duct 23. Through the arrangement, the first coil 21 and the second coil 22 can be uniformly cooled, and the performance of the transformer 100 can be optimized, so that the transformer has a longer service life.

As an alternative embodiment, one of the first coil 21 and the second coil 22 may be a high voltage coil, and the other may be a low voltage coil, so as to better meet the performance requirement of the transformer 100. In some examples, the first coil 21 may be a low voltage coil and the second coil 22 may be a high voltage coil.

Referring to fig. 5, in some alternative embodiments, the coil assembly 20 provided in each of the above embodiments may have one first coil 21 and one second coil 22, which is an alternative embodiment, but not limited to the above embodiments, in some other examples, the number of the first coils 21 may also be more than two, similarly, more than two first coils 21 are located between the iron core 10 and the second coil 22, a second annular air duct 24 is formed between every two adjacent first coils 21, and a phase change heat pipe 30 is disposed in at least one second annular air duct 24.

When the first coil 21 is a low-voltage coil, because the current change at the low-voltage coil side is large, the heat productivity is high, therefore, the second annular air duct 24 is formed in two adjacent first coils 21, which can not only facilitate the heat dissipation between two adjacent first coils 21, but also provide the installation space for the phase-change heat conduction pipe 30, so that the phase-change heat conduction pipe 30 can be arranged in the second annular air duct 24 between two adjacent first coils 21, and further the phase-change performance of the cooling liquid 32 in the phase-change heat conduction pipe 30 can be utilized to realize the heat dissipation and cooling requirements for two adjacent first coils 21.

As an alternative embodiment, the phase-change heat conductive pipe 30 may be disposed in the second annular air duct 24 formed between each adjacent two of the first coils 21. So as to better cool the coil assembly 20 and ensure the safe and stable operation of the transformer 100.

Likewise, as an alternative embodiment, in the transformer 100 provided in the foregoing embodiments, the number of the phase change heat conducting pipes 30 in each second annular air duct 24 may be one, and certainly, may also be multiple, when there are multiple phase change heat conducting pipes 30, the multiple phase change heat conducting pipes 30 are arranged at intervals, and optionally, the multiple phase change heat conducting pipes 30 may be distributed at intervals and uniformly.

Alternatively, the phase change heat conducting pipe 30 located in the second annular air duct 24 may be fixed by the clamping force of two adjacent first coils 21, and of course, in some examples, the winding portion of one of the first coils 21 may be wound around the outer circumferential wall of the phase change heat conducting pipe 30, which may also satisfy the position limitation of the phase change heat conducting pipe 30.

Alternatively, the number of the first coils 21 may be two, three or even more, and may be determined according to the performance requirement of the transformer 100, and the number is not limited herein.

Optionally, when the transformer 100 includes the first annular air duct 23 and the second annular air duct 24 at the same time, the phase change heat pipe 30 may be disposed inside only one of the first annular air duct 23 and the second annular air duct 24, and of course, in order to better meet the cooling requirement of the transformer 100, optionally, the phase change heat pipes 30 may be disposed inside both the first annular air duct 23 and the second annular air duct 24 at the same time, so as to implement heat dissipation and cooling of the first coil 21 and the second coil 22.

Alternatively, the number of the phase change heat pipes 30 in the first annular air duct 23 and the number of the phase change heat pipes 30 in the second annular air duct 24 may be the same, or may be different as long as the cooling requirement of the coil assembly 20 can be met.

With continued reference to fig. 6, as an alternative implementation manner, in the transformer 100 provided in the above embodiments, the phase change heat pipe 30 is inserted into the second coil 22, since the high voltage side of the transformer 100 may also have a higher current in some examples, by inserting the phase change heat pipe 30 into the second coil 22, the second coil 22 can be cooled repeatedly by the heat exchange between the phase change heat pipe 30 and the second coil 30 through the cyclic phase change process of vaporization-liquefaction-vaporization-liquefaction of the cooling liquid 32 in the phase change heat pipe 30, so as to further optimize the cooling performance of the transformer 100 itself.

In practical implementation, the number of the phase change heat pipes 30 in the second coil 22 may be one, or may be two or more, and when the number is two or more, the two or more phase change heat pipes 30 may be spaced apart from each other and uniformly distributed.

In some alternative embodiments, the phase change heat pipe 30 located within the second coil 22 may be wrapped by the windings of the second coil 22 and at least partially secured within the interior of the second coil 22 when the second coil 22 is formed.

As an alternative implementation, with reference to fig. 2 to fig. 6, the transformer 100 provided in the above embodiments further includes a protective casing 40, the iron core 10 and the coil assembly 20 are located in the protective casing 40, the protective casing 40 has an upper cover 41, the upper cover 41 is provided with a number of through holes 42 not less than the number of the phase change heat pipes 30, each phase change heat pipe 30 is in clearance fit with the through hole 42, and the condensation section 30b protrudes from the upper cover 41. With the above arrangement, the iron core 10, the coil assembly 20, and the like can be protected by the protective case 40, and the through holes 42 formed in the upper cover 41 can limit the phase change heat pipes 30, thereby preventing relative displacement between the phase change heat pipes 30 and the coil assembly 20. The cooling performance and the safety performance of the transformer 100 are ensured.

Referring to fig. 7 and 8, as an alternative implementation, in the transformer 100 according to the embodiments, the phase-change heat pipe 30 further includes a wick 33, the wick 33 is disposed in the closed cavity 311 and attached to the inner wall of the tube shell 31, and the wick 33 is made of a capillary porous material. By arranging the wick 33 in the phase-change heat pipe 30, the vaporized cooling liquid 32 can flow back to the evaporation section 30a along the porous material of the wick 33 under the action of capillary force after being liquefied, which is more beneficial to the backflow of the cooled cooling liquid 32, so that the cooling liquid can flow back to the bottom of the phase-change heat pipe 30 under the action of capillary force, and further, the uniform performance of cooling and heat dissipation of the coil assembly 20 is ensured.

In some alternative embodiments, as shown in fig. 8, the transformer 100 of the above embodiments, the wick 33 includes two or more mesh layers 331 sequentially stacked along the inner wall, wherein the mesh number of the mesh layers 331 disposed near the inner wall of the case 31 is smaller than the mesh number of the mesh layers 331 disposed far from the inner wall of the case 31. Through the arrangement, a fine mesh network with small mesh number on the outer side provides larger capillary suction pressure, and a coarse mesh network with large mesh number in the channel enables the liquid flow resistance to be smaller, so that the cooling liquid 32 after being converted into the cooling liquid 32 can better flow back to the evaporation section 30 a.

As an alternative embodiment, referring to fig. 2 to 8, in the transformer 100 provided in the above embodiments, the number of the iron cores 10 is more than two and the iron cores 10 are arranged at intervals, each iron core 10 is provided with a coil assembly 20, and a phase change heat pipe 30 is inserted into at least one coil assembly 20. Through the above arrangement, a plurality of setting requirements of the transformer 100 can be satisfied. In some alternative embodiments, a phase-change heat pipe 30 may be inserted into each coil assembly 20, so that the transformer 100 has better heat dissipation and cooling performance and higher safety.

Therefore, the transformer 100 according to the embodiment of the present invention includes the iron core 10, the coil assembly 20 and the phase change heat pipe 30, the coil assembly 20 is disposed around the iron core 10, the phase change heat pipe 30 includes the tube shell 31 having the closed cavity 311 and the cooling liquid 32 disposed in the closed cavity 311, and in the height direction X of the iron core 10, the phase change heat pipe 30 includes the evaporation section 30a and the condensation section 30b disposed oppositely, the cooling liquid 32 is located in the evaporation section 30a, the condensation section 30b protrudes from the coil assembly 20 in the height direction X, and the phase change heat pipe 30 is inserted into the coil assembly 20, so that the phase change heat pipe 30 can perform heat exchange with the coil assembly 20 through the evaporation section 30a to evaporate the cooling liquid 32 to the condensation section 30b, only after the condensation section 30b is provided with the cooling medium matched with the condensation section 30b to liquefy the evaporated cooling liquid 32 again and then return to the evaporation section 30a, the circulative cooling coil assembly 20 utilizes the phase change principle of the cooling liquid 32 in the phase change cooling pipe to realize the cooling and heat dissipation requirements on the interior of the transformer 100, and does not need devices such as a circulating pump to realize the flowing of the cooling liquid 32, so that the whole cooling power consumption of the transformer 100 is low and the cost is low.

Referring to fig. 9 and 10, an embodiment of the invention further provides a cooling system for the transformer 100, the cooling system includes a heat sink 200 and a cooling component 300, the heat sink 200 has a matching portion 210, and the matching portion 210 is used for contacting with the condensation section 30b of the phase-change heat conducting pipe 30. The cooling part 300 is disposed opposite to the radiator 200 and supplies a cooling medium to the radiator 200, and the cooling medium flows through the radiator 200 and exchanges heat with the radiator 200 to liquefy the coolant 32 vaporized in the condensation section 30b and flow back to the evaporation section 30 a.

In some alternative embodiments, the heat sink 200 of the cooling system according to the present invention includes a plurality of heat dissipating fins 210a distributed at intervals, two adjacent heat dissipating fins 210a together form the fitting portion 210, and the condensing section 30b of the phase-change heat conductive pipe 30 is clamped between two adjacent heat dissipating fins 210 a. Through the above arrangement, the radiator 200 has a simple overall structure and low cost, and adopts the form of the plurality of radiating fins 210a, so that the radiating effect is better, and the liquefying reflux requirement of the steam of the cooling liquid 32 in the condensation section 30b of the phase change heat pipe 30 can be better met.

As an alternative implementation manner, in the cooling system provided in each of the above embodiments, the cooling component 300 includes a blower, the blower includes an air inlet 310 and an air outlet 320, the air inlet 310 is provided with the filtering component 400, and the air outlet 320 is disposed facing the heat sink 200. Through the arrangement, on the basis of meeting the requirement of heat exchange with the radiator 200, the cooling medium flowing to the radiator 200 can be cleaner, and the influence on the performance of the radiator 200 or other equipment caused by the existence of magazines in the cooling medium is avoided.

Therefore, the cooling system provided by the embodiment of the present invention can be used for the transformer 100 of each of the above embodiments, the fitting portion 210 of the heat sink 200 is in contact with the condensation section 30b, the condensation section 30b can exchange heat with the heat sink 200, so that heat of the vapor of the cooling liquid 32 in the condensation section 30b is transferred to the heat sink 200, the vapor of the cooling liquid 32 is cooled and liquefied, and the heat transferred to the heat sink 200 exchanges heat with the cooling medium under the action of the cooling medium provided by the cooling component 300, so that the heat sink 200 is cooled again and used for liquefying and refluxing the vapor in the condensation section 30 b.

Referring to fig. 11 and 12, an embodiment of the invention further provides a wind turbine generator set, which may include a tower 500, a nacelle 600, a generator 700, an impeller 800, the transformer 100 of the above embodiments, and the cooling system of the above embodiments, wherein the nacelle 600 is disposed at a top end of the tower 500, and the generator 700 is disposed in the nacelle 600, which may be located inside the nacelle 600, or may be located outside the nacelle 600. The impeller 800 includes a hub 810 and a plurality of blades 820 connected to the hub 810, and the impeller 800 is connected to the generator 700 through the hub 810 thereof to drive the rotor of the generator 700 to rotate, so as to meet the power generation requirement of the wind turbine generator system.

Optionally, the tower 500 of the wind turbine generator system includes a cylinder wall 510 and an accommodating cavity 520 enclosed by the cylinder wall 510, an opening 530 is provided on the cylinder wall 510 and is communicated with the accommodating cavity 520, the transformer 100 is disposed in the accommodating cavity 520, and the phase change heat conducting pipe 30 extends along an axial direction of the tower 500. The power transmission task of the wind turbine generator system is realized by the transformer 100.

The heat sink 200 of the cooling system is disposed in the accommodating chamber 520, and optionally, the heat sink 200 is in contact with the condensation section 30b of the phase-change heat conductive pipe 30 through the fitting portion 210. The cooling part 300 is located outside the accommodating chamber 520 and connected to the cylinder wall 510, and the cooling medium provided by the cooling part 300 flows to the radiator 200 through the opening 530 and exchanges heat with the radiator 200.

The wind generating set provided by the embodiment of the invention can meet the wind power generation requirement, and the transformer 100 and the cooling system of the embodiments are included, and meanwhile, the transformer 100 is provided with the phase change heat conduction pipe 30 in the coil component 20 and is provided with the corresponding cooling system, so that the transformer 100 can realize heat dissipation by utilizing the cyclic phase change process of vaporization-liquefaction-vaporization-liquefaction of the cooling liquid 32 in the phase change heat conduction pipe 30, and the safety performance is high on the basis of meeting the power transmission requirement. Meanwhile, devices such as a circulating pump and the like are not required to be arranged, so that the whole power consumption of the wind generating set is small, the cost is low, the higher power generation benefit is achieved, and compared with the prior art, the wind generating set does not need to be provided with parts such as the circulating pump and the like, the space is saved, the whole power density is higher, the noise is low, and the wind generating set is easy to popularize and use.

While the invention has been described with reference to a preferred embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the technical features mentioned in the embodiments can be combined in any way as long as there is no structural conflict. It is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.