阅读说明：本技术 空气冷却系统、风力发电机组及其冷却方法 (Air cooling system, wind generating set and cooling method thereof ) 是由 白洛林 彼得·海赛尔伦德·瑟琳森 张敬祎 于 2019-11-01 设计创作，主要内容包括：本发明涉及一种空气冷却系统、风力发电机组及其冷却方法。空气冷却系统设置于风力发电机组的机舱与发电机的进气口之间,其包括：各自独立运行的两个以上的子系统,每个子系统包括：除湿装置,设置于机舱的壁部且与机舱连通；驱动设备,设置于机舱内,以将外界冷却空气经除湿装置引入机舱,与由发电机的出气口排放的部分高温空气混合,并与机舱的发热部件和/或发电机进行热交换；其中,两个以上子系统的驱动设备同时运行,以实现第一功能；两个以上子系统的驱动设备分别交替运行预定时间,以实现第二功能。该空气冷却系统扩展了空气冷却系统的功能性。(The invention relates to an air cooling system, a wind generating set and a cooling method thereof. Air cooling system sets up between wind generating set's cabin and the air inlet of generator, and it includes: two or more subsystems each operating independently, each subsystem comprising: a dehumidifier device provided on a wall of the nacelle and communicating with the nacelle; a driving device disposed in the nacelle to introduce the outside cooling air into the nacelle through the dehumidifying apparatus, mix with a part of the high temperature air discharged from the air outlet of the generator, and exchange heat with the heat generating components of the nacelle and/or the generator; wherein the driving devices of more than two subsystems operate simultaneously to realize a first function; the driving devices of more than two subsystems are respectively operated alternately for a preset time to realize the second function. The air cooling system extends the functionality of the air cooling system.)

1. An air cooling system arranged between a nacelle (C) of a wind turbine and an air intake (In) of a generator (M), characterized In that it comprises two or more subsystems (S) each operating independently, each of said subsystems (S) comprising at least:

a dehumidifier (2) provided on a wall of the nacelle (C) and communicating with the nacelle (C);

a driving device (3) disposed in the nacelle (C) to introduce outside cooling air into the nacelle (C) through the dehumidifying apparatus (2), mix with a portion of high-temperature air discharged from the air outlet (O) of the generator (M), and exchange heat with heat generating components of the nacelle (C) and/or the generator (M);

wherein the driving devices (3) of two or more of the subsystems (S) are operated simultaneously to realize a first function; the driving devices (3) of more than two subsystems (S) are respectively operated alternately for a preset time to realize a second function.

2. An air cooling system according to claim 1, wherein the first function is at least one of cooling, dehumidifying and de-salting the wind turbine generator set, and the second function is de-icing the dehumidifying device (2).

3. Air cooling system according to claim 1, characterised in that the structure of two or more subsystems (S) is identical.

4. Air cooling system according to claim 2, wherein each of said subsystems (S) further comprises:

-a first duct (1) having a first end (11) inside the nacelle (C) and a second end (12) outside the nacelle (C), the drive apparatus (3) being arranged in correspondence of the first end (11) of the first duct (1), the dehumidifying device (2) being arranged in correspondence of the second end (12) of the first duct (1) in the wall of the nacelle (C);

and one end of the second pipeline (5) is connected with the air outlet (O) of the generator (M), and the other end of the second pipeline extends to the outside of the cabin (C) to be communicated with the outside cooling air after intersecting with the first pipeline (1), so that part of high-temperature air discharged from the air outlet (O) of the generator (M) is mixed with the cooling air entering the first pipeline (1).

5. An air cooling system according to claim 2 or 4, characterized in that it further comprises a temperature sensor and a controller electrically connected to said temperature sensor, said controller controlling said driving devices (3) of two or more of said subsystems (S) to operate alternately for a predetermined time respectively, to de-ice said dehumidifying means (2) of each of said subsystems (S), when the outside ambient temperature monitored by said temperature sensor is lower than a predetermined temperature.

6. An air cooling system according to claim 4, characterized in that each subsystem (S) further comprises a regulating valve (5), said regulating valve (5) being arranged at the intersection of the first duct (1) and the second duct (4) to regulate the flow of high temperature air entering the first duct (1) from the second duct (4).

7. Air cooling system according to claim 4, characterized in that each of said subsystems (S) further comprises a filtering device (6), said filtering device (6) dividing the internal space of the nacelle (C) into a first cavity (C1) and a second cavity (C2), said first duct (1) and said driving apparatus (3) being located in said first cavity (C1).

8. An air cooling system according to claim 7, characterized in that the filter device (6) comprises an insulating bracket (61) and a filter assembly arranged on the insulating bracket (61), the insulating bracket (61) being connected with a wall of the nacelle (C) and being arranged tapering in the direction of flow of the air in the first cavity (C1).

9. The air cooling system according to claim 8, wherein the filter assembly includes a first filter element (621) disposed adjacent to the first cavity (C1) and a second filter element (622) disposed adjacent to the second cavity (C2), and a filter mesh diameter of the second filter element (622) is smaller than a filter mesh diameter of the first filter element (621).

10. An air cooling system according to claim 4, wherein each of said subsystems (S) further comprises a plurality of subducts (41) provided inside said nacelle (C) and communicating with the outside, said plurality of subducts (41) communicating with said second duct (4) to discharge the high temperature air generated by said generator (M) outside said nacelle (C) through said plurality of subducts (41).

11. Air cooling system according to claim 1, further comprising a third duct (7), wherein the generator (M) is further provided with an auxiliary air outlet (a) arranged in or outside the cabin (C), and wherein one end of the third duct (7) is connected to the auxiliary air outlet (a) and the other end is in communication with the outside.

12. Air cooling system according to claim 11, wherein said auxiliary air outlet (a) corresponds to an internal arrangement of said nacelle (C);

each of the sub-systems (S) further comprises a plurality of sub-ducts (41) provided inside the nacelle (C) and communicating with the outside, the plurality of sub-ducts (41) communicating with the third duct (7) to discharge high-temperature air generated by the generator (M) outside the nacelle (C) through the plurality of sub-ducts (41).

13. Air cooling system according to claim 10 or 12, wherein a plurality of said subducts (41) of two or more of said subsystems (S) are circumferentially distributed alternately within said nacelle (C).

14. Air cooling system according to claim 4, characterised in that the second ducts (4) of two or more subsystems (S) are arranged separately or integrally.

15. A wind turbine generator set, comprising:

a generator (M);

a nacelle (C) connected with the generator (M); and

the air cooling system of any one of claims 1 to 14, which is arranged between the nacelle (C) and the air intake (In) of the generator (M).

16. A method of cooling a wind park according to claim 15, wherein the method of cooling comprises:

acquiring running instruction information, wherein the running instruction comprises a first instruction and a second instruction;

when the first instruction is obtained, simultaneously starting driving equipment (3) of N subsystems (S) to realize a first function, wherein N is more than or equal to 2;

when the second instruction is acquired, the driving devices (3) of the N subsystems (S) are alternately operated for a predetermined time to realize a second function.

17. The cooling method of claim 16, wherein the performing a first function comprises:

-a drive device (3) for simultaneously activating N subsystems (S), each subsystem (S) comprising at least a dehumidifying device (2) arranged in a wall of a nacelle (C) and communicating with said nacelle (C), and a drive device (3) arranged in said nacelle (C);

the outside cooling air enters the cabin (C) through the dehumidifying device (2) under the action of the driving equipment (3) of the N subsystems (S), is mixed with part of high-temperature air discharged by the air outlet (O) of the generator (M), and exchanges heat with the heat generating components of the cabin (C) and/or the generator (M).

18. The cooling method of claim 16, wherein said performing a second function comprises:

monitoring whether the ambient temperature outside the cabin (C) is below a predetermined temperature;

if yes, starting a driving device (3) of the ith subsystem (S) in the N subsystems (S), operating for a preset time, and realizing the deicing of the dehumidifying devices (2) of the rest subsystems (S) in the N subsystems (S), wherein i is more than or equal to 1 and less than N;

and closing the driving equipment (3) of the ith subsystem (S), starting the driving equipment (3) of the (i + 1) th subsystem (S), and operating for a preset time to realize the deicing of the dehumidifying device (2) of the rest subsystems (S) in the N subsystems (S).

Technical Field

The invention relates to the technical field of cooling, in particular to an air cooling system, a wind generating set and a cooling method thereof.

Background

Wind power generation is one of the closest renewable energy technologies to commercialization, and is the focus of renewable energy development. The motor in the wind generating set has heat loss in the operation process, and the heat loss mainly comprises the following steps: electromagnetic losses, i.e., joule heating in the winding due to ohmic resistance, i.e., copper losses; hysteresis loss and eddy current loss in the iron core, etc., i.e., iron loss; and unavoidable stray losses; if the permanent magnet motor is adopted, the magnetic steel loss is also included. These losses cause the motor to release a large amount of heat during operation, and the heat will not only cause a certain impact on the motor itself and its insulation structure, resulting in a shortened insulation life, even insulation failure, but also in a continuous decrease in the output power of the motor.

With the rapid development of wind generating sets, the unit capacity of the set is continuously increased, the loss of the wind generating set is continuously improved, and the design of a cooling system is more and more important. Especially, when the wind generating set is in the working conditions of large wind sand, humidity, low temperature, high salt and other severe environments, the functional requirements on the cooling system are also more severe.

Disclosure of Invention

The invention aims to provide an air cooling system, a wind generating set and a cooling method thereof, wherein the air cooling system can realize multiple functions including a cooling function.

In one aspect, the present invention provides an air cooling system disposed between a nacelle of a wind turbine generator system and an air intake of a generator, the air cooling system at least comprising: two or more subsystems each operating independently, each subsystem comprising: a dehumidifier device provided on a wall of the nacelle and communicating with the nacelle; a driving device disposed in the nacelle to introduce the outside cooling air into the nacelle through the dehumidifying apparatus, mix with a part of the high temperature air discharged from the air outlet of the generator, and exchange heat with the heat generating components of the nacelle and/or the generator; wherein the driving devices of more than two subsystems operate simultaneously to realize a first function; the driving devices of more than two subsystems are respectively operated alternately for a preset time to realize the second function.

According to an aspect of the invention, the first function is at least one of cooling, dehumidifying and de-salting the wind park and the second function is de-icing the dehumidifying device.

According to one aspect of the invention, the more than two subsystems are structurally identical.

According to one aspect of the invention, each subsystem further comprises: a first duct having a first end located inside the nacelle and a second end located outside the nacelle, the driving device being disposed corresponding to the first end of the first duct, the dehumidifying apparatus being disposed corresponding to the second end of the first duct at a wall portion of the nacelle; and one end of the second pipeline is connected with the air outlet of the generator, and the other end of the second pipeline extends to the outside of the engine room to be communicated with the outside cooling air after intersecting with the first pipeline so as to mix part of high-temperature air discharged from the air outlet of the generator with the cooling air entering the first pipeline.

According to one aspect of the invention, the air cooling system further comprises a temperature sensor and a controller electrically connected with the temperature sensor, wherein when the external environment temperature monitored by the temperature sensor is lower than a preset temperature, the controller controls the driving devices of the two or more subsystems to alternately operate for a preset time respectively so as to deice the dehumidifying device of each subsystem.

According to one aspect of the invention, each subsystem further comprises a regulating valve disposed at an intersection of the first and second conduits to regulate a flow of high temperature air from the second conduit into the first conduit.

According to an aspect of the invention, each subsystem further comprises a filter device dividing the interior space of the nacelle into a first cavity and a second cavity, the first duct and the drive equipment being located in the first cavity.

According to one aspect of the invention, the filter device comprises an insulating support and a filter assembly arranged on the insulating support, the insulating support being connected to a wall of the nacelle and being arranged tapering in the direction of flow of the air in the first cavity.

According to one aspect of the invention, the filter assembly includes a first filter element disposed adjacent the first cavity and a second filter element disposed adjacent the second cavity, the second filter element having a smaller mesh size than the first filter element.

According to an aspect of the present invention, each of the subsystems further includes a plurality of sub-ducts disposed in the nacelle and communicating with the outside, the plurality of sub-ducts communicating with the second duct to discharge high-temperature air generated by the generator to the outside of the nacelle through the plurality of sub-ducts.

According to one aspect of the invention, the air cooling system further comprises a third pipeline, the generator is further provided with an auxiliary air outlet, the auxiliary air outlet is arranged in the engine room or outside the engine room, one end of the third pipeline is connected with the auxiliary air outlet, and the other end of the third pipeline is communicated with the outside.

According to one aspect of the invention, the auxiliary air outlet of the generator is arranged corresponding to the engine room; each subsystem further comprises a plurality of sub-pipelines which are arranged in the engine room and communicated with the outside, and the plurality of sub-pipelines are communicated with the third pipeline so as to discharge high-temperature air generated by the generator to the outside of the engine room through the plurality of sub-pipelines.

According to one aspect of the invention, the plurality of subducts of the two or more subsystems are circumferentially alternately distributed within the nacelle.

According to one aspect of the invention, the second pipes of the two or more subsystems are arranged separately or integrally.

In another aspect, the present invention further provides a wind turbine generator system, including: a generator; a nacelle connected with the generator; and an air cooling system as in any of the preceding, arranged between the nacelle and the air intake of the generator.

In another aspect, the present invention further provides a cooling method for a wind turbine generator system as described above, including: acquiring running instruction information, wherein the running instruction comprises a first instruction and a second instruction; when a first instruction is obtained, simultaneously starting driving equipment of N subsystems to realize a first function, wherein N is more than or equal to 2; and when the second instruction is acquired, the driving devices of the N subsystems respectively operate alternately for a preset time so as to realize a second function.

According to one aspect of the invention, implementing the first function comprises: simultaneously starting driving equipment of the N subsystems, wherein each subsystem at least comprises a dehumidifying device which is arranged on the wall of the cabin and communicated with the cabin and the driving equipment which is arranged in the cabin; and the outside cooling air enters the cabin through the dehumidifying device under the action of the driving devices of the N subsystems, is mixed with part of high-temperature air discharged from the air outlet of the generator, and exchanges heat with the heat generating components of the cabin and/or the generator.

According to one aspect of the invention, implementing the second function comprises: monitoring whether an ambient temperature outside the nacelle is below a predetermined temperature; if yes, starting the driving equipment of the ith subsystem in the N subsystems, operating for preset time, and deicing the dehumidification devices of the rest subsystems in the N subsystems, wherein i is more than or equal to 1 and is less than N; and closing the driving equipment of the ith subsystem, starting the driving equipment of the (i + 1) th subsystem, and operating for a preset time to realize the deicing of the dehumidifying devices of the rest subsystems in the N subsystems so as to realize the second function.

According to the air cooling system and the wind generating set provided by the invention, more than two subsystems which respectively and independently operate are arranged between the engine room of the wind generating set and the air inlet of the generator, and the driving devices of the more than two subsystems simultaneously operate, so that a first function can be realized; the driving devices of more than two subsystems respectively operate alternately for preset time, so that the second function can be realized, the waste heat of the generator is fully utilized, the two subsystems act in a synergistic manner, and the functionality of the air cooling system is expanded. In addition, more than two subsystems operate independently, when one subsystem fails, the operation of the other subsystem is not influenced, and the fault tolerance and reliability of the air cooling system are improved; and the air cooling system has high cooling efficiency, simple and compact structure, small occupied space, lower cost and convenient maintenance. In addition, according to the cooling method of the wind generating set, different functions can be realized according to different received instructions, and the reliability of the wind generating set is improved.

Drawings

FIG. 1 is a schematic structural diagram of an air cooling system according to an embodiment of the present invention;

FIG. 2 is a schematic illustration of a layout of the ducts within the nacelle of the air cooling system shown in FIG. 1;

FIG. 3 is a schematic structural diagram of another air cooling system provided by an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of another air cooling system provided by an embodiment of the present invention;

FIG. 5 is a schematic illustration of the layout of the ducts within the nacelle of the air cooling system shown in FIG. 4;

FIG. 6 is a schematic structural diagram of another air cooling system provided by an embodiment of the present invention;

fig. 7 is a flow chart of a cooling method of a wind turbine generator system according to an embodiment of the present invention.

Wherein:

an M-generator; c-engine room; an In-gas inlet; an O-outlet; a-an auxiliary gas outlet; an S-subsystem; f-filter element; c1 — first cavity; c2 — second cavity;

1-a first conduit; 11-a first end; 12-a second end;

2-a dehumidifying device;

3-driving the device;

4-a second conduit; 41-subduct; 42-a first circulation fan;

5-adjusting the valve; 6-a filtration device; 61-an isolating support; 621-a first filter element; 622 — second filter;

7-a third conduit; 71-second circulation fan.

In the drawings, like parts are designated with like reference numerals, and the drawings 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, well-known structures and techniques, at least in part, are not shown in order to avoid unnecessarily obscuring the present invention; also, the size of the region 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 reference to the orientation words as shown in the drawings, and is not intended to limit the specific structure 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 being either fixedly connected, detachably connected, or integrally connected; 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.

For better understanding of the present invention, an air cooling system, a wind turbine generator set and a cooling method thereof according to an embodiment of the present invention will be described in detail below with reference to fig. 1 to 7.

Since the ambient air outside the nacelle C of the wind park generally has a certain relative humidity, especially for offshore wind parks, which is air with high salt and humidity, and mostly exists in the form of liquid droplet particles, it is necessary to desalt and dehumidify the outside cooling air before entering the nacelle C. When the ambient temperature outside the cabin C is lower than a predetermined temperature, for example, when operating in a cold region in winter, the dehumidifying apparatus 2 of the cabin C is usually frozen due to the fact that the outside cooling air is in a humid, low-temperature environment, blocking the passage into the cabin C, and also requiring deicing work.

Referring to fig. 1, an embodiment of the present invention provides an air cooling system disposed between a cabin C of a wind turbine generator system and an air inlet In of a generator M, where the air cooling system includes more than two subsystems S that operate independently. Each subsystem S comprises at least: a dehumidifying apparatus 2 and a driving device 3.

The dehumidifier 2 is provided on a wall of the nacelle C and communicates with the nacelle C. The dehumidifying apparatus 2 may be, for example, a gas-liquid separator, which may be disposed on an inner wall or an outer wall of the cabin C, for separating liquid droplets from the outside cooling air.

The driving device 3 is provided in the cabin C to introduce outside cooling air into the cabin C through the dehumidifying apparatus 2. Due to the effect of inertia, the majority of the droplet particles, for example, with a diameter of more than 12 μ M, will impinge on the blades of the wind turbine and then flow out of the nacelle C, after removal of the large-diameter droplet particles, the remaining humid air, containing a small amount of moisture and a small amount of salt, is introduced into the nacelle by the drive means 3 via the dehumidifying device 2, mixed with part of the hot air discharged by the air outlet O of the generator M, filtered (the re-filtering device is described in detail below), and subjected to heat exchange with the heat generating components of the nacelle C and/or the generator M.

Alternatively, the driving device 3 is a centrifugal fan comprising a driving motor and a fan blade, which is driven to rotate by the driving motor. The heat generating components in the nacelle C include, for example, but are not limited to, various electrical equipment, a gearbox, etc., depending on the specific layout of the wind turbine.

Wherein the driving devices 3 of more than two subsystems S operate simultaneously to implement a first function; the driving devices 3 of the two or more subsystems S are alternately operated for a predetermined time, respectively, to implement the second function.

Optionally, the first function is at least one of cooling, dehumidifying and de-salting the wind park and the second function is de-icing the dehumidifier 2.

According to the air cooling system provided by the invention, more than two subsystems S which respectively and independently operate are arranged between the cabin C of the wind generating set and the air inlet E of the generator M, and the driving devices 3 of the more than two subsystems S operate simultaneously, so that a first function can be realized; the driving devices 3 of more than two subsystems S respectively run alternately for preset time, the second function can be realized, the waste heat of the generator is fully utilized, the two subsystems S are cooperated, and the functionality of the air cooling system is expanded. In addition, more than two subsystems S operate independently, when one subsystem S fails, the operation of the other subsystem S is not influenced, and the fault tolerance and the reliability of the air cooling system are improved; and the air cooling system has high cooling efficiency, simple and compact structure, small occupied space, lower cost and convenient maintenance.

The specific structure of the air cooling system provided by the embodiment of the invention is further described in detail in the following with reference to the accompanying drawings.

Referring again to fig. 1, the structure of each subsystem S of the air cooling system may be identical, thus eliminating a complicated setup and simplifying the entire air cooling system. Specifically, the single subsystem S further includes: a first conduit 1 and a second conduit 4.

The first duct 1 has a first end 11 located inside the cabin C and a second end 12 located outside the cabin C, the driving device 3 is arranged in correspondence with the first end 11 of the first duct 1, and the dehumidifying apparatus 2 is arranged in correspondence with the second end 12 of the first duct 1 in a wall portion of the cabin C, here an inner wall of the cabin C, but also an outer wall of the cabin C, preferably in the outer wall of the cabin C, so that the cooling air entering the cabin C passes through the dehumidifying apparatus 2 entirely without occupying the inner space of the cabin C.

One end of the second pipeline 4 is connected with the air outlet O of the generator M, and the other end of the second pipeline extends to the outside of the cabin C after intersecting with the first pipeline 1 and is communicated with outside cooling air so as to mix part of high-temperature air discharged from the air outlet O of the generator M with the cooling air entering the first pipeline 1.

Preferably, the driving device 3 is disposed in a downstream region where the first duct 1 and the second duct 4 meet, and the outside cooling air is mixed with high-temperature exhaust gas (temperature may reach more than 90 degrees celsius) of the generator M, increasing the temperature of the outside cooling air and reducing the humidity of the outside cooling air. It has been found that under certain relative humidity conditions, for example, 74% relative humidity, the salt can exist in the air as liquid salt, and therefore, the relative humidity of the mixed gas is controlled to be lower than 74%, preferably lower than 60%, and the liquid salt contained in the mixed air can be dried, solidified and automatically precipitated.

The driving device 3 is arranged in the downstream area of the junction of the first pipeline 1 and the second pipeline 4, so that the gases in the first pipeline 1 and the second pipeline 4 can be better driven to be fully mixed, the relative humidity of mixed air is controlled, and the salt is solidified and removed; it is also possible to avoid that the salt in the ambient air attacks the drive equipment 3 and thus the nacelle C and the generator M. Thus, the mixed air is heat-exchanged with the heat generating components of the cabin C and/or the generator M. The high-temperature waste heat gas discharged by the generator M can be fully utilized, the energy consumption is reduced, the external cooling air can be dehumidified and desalted, and heating components in the cabin C of the wind generating set and/or the generator M can be directly cooled.

From this, this air cooling system adopts the mode of external cooling air direct cooling, and the cooling temperature is low to more than two subsystems S get into first pipeline 1 under the effect of drive arrangement 3 separately, mix the back with the high-temperature air who discharges to second pipeline 4 by generator M 'S gas outlet O, join to cabin C in jointly, greatly improved wind generating set' S cooling efficiency. Because the risk of corrosion leakage does not exist, the reliability is higher than that of a liquid cooling or air-liquid integrated cooling mode, meanwhile, complex parts such as liquid cooling pipelines, pump stations, heat exchangers, voltage stabilizing systems and the like are saved, the structure is compact, the occupied space is small, the maintenance is convenient, and the manufacturing cost is lower.

Further, the air cooling system provided by the embodiment of the invention further comprises: a temperature sensor and a controller (not shown) electrically connected to the temperature sensor.

Optionally, a temperature sensor is provided at a wall of the nacelle C for monitoring the ambient temperature outside the nacelle C. When the external environment temperature monitored by the temperature sensor is lower than the preset temperature, the controller controls the driving devices 3 of more than two subsystems S to alternately operate for the preset time respectively so as to deice the dehumidifying device 2 of each subsystem S. The predetermined temperature is, for example, 0 ℃ and the predetermined time is, for example, 10 minutes to 30 minutes.

The working principle of deicing is as follows: when the driving device 3 of the first subsystem S is operated, the pressure in the cabin C increases, and since the driving devices 3 of the remaining subsystems S are not turned on, the air with high pressure will diffuse outward through the driving device 3 and the first duct 1 of the second subsystem S that are not turned on, and since the air temperature in the cabin C is higher than the outside ambient temperature, the first duct 1 and the dehumidifying apparatus 2 of the second subsystem S can be deiced.

After the driving device 3 of the first subsystem S operates for a predetermined time, the driving device 3 of the first subsystem S is closed, and then the driving device 3 of the second subsystem S is started, and according to the same working principle, the pressure in the cabin C is increased, the air with high pressure can diffuse outwards through the non-activated driving devices 3 and the first pipelines 1 of the other subsystems S, and because the temperature of the air in the cabin C is higher than the external environment temperature, the first pipelines 1 and the dehumidifying device 2 of the other subsystems S can be deiced after the operation for the predetermined time,

and in the same way, the first pipeline 1 and the first dehumidification system 2 of each of the more than two subsystems S are deiced. After the deicing operation is finished, the first pipelines 1 of more than two subsystems S can be communicated with the outside air.

Further, each subsystem S further includes a regulating valve 5, and the regulating valve 5 is disposed at the intersection of the first pipeline 1 and the second pipeline 4 to regulate the flow rate of the high-temperature air entering the first pipeline 1 from the second pipeline 4.

The regulating valve 5 is preferably a three-way valve, which is in communication with the first conduit 1, the second conduit 4 and the outside cooling air, respectively. A part of high-temperature air discharged to the second pipeline 4 from the air outlet O of the generator M enters the first pipeline 1 through the regulating valve 5, and most of the rest high-temperature air is discharged out of the cabin C through the second pipeline 4. The high temperature air entering the first pipeline 1 is mixed with air containing high salt and high humidity, the temperature is increased, the mixture becomes unstable saturated salt solution particles and air, the relative humidity of the mixed gas is controlled to be lower than 74%, preferably lower than 60% through the adjusting valve 5, the mixture is separated out salt crystals in a crystallization form under the rotation action of the driving device 3, most of the salt crystals fall into a storage box (not shown in the figure) of the cabin C, and the other part of the salt crystals are filtered and removed through the filtering device 6, so that the desalting and dehumidifying effects on the outside cooling air are improved.

Further, the second pipeline 4 is provided with a first circulating fan 42 to improve the mixing efficiency of the high-temperature air in the second pipeline 4 and the humid air in the first pipeline 1, and improve the desalting and dehumidifying effects of the outside cooling air.

Further, each subsystem S further includes a filter device 6, the filter device 6 divides the internal space of the cabin C into a first cavity C1 and a second cavity C2, the first duct 1 and the driving device 3 are located in the first cavity C1, and the filter device 6 is used for removing particles such as dust, salt and the like remaining in the mixed air.

Optionally, the filtering device 6 comprises an insulating support 61 and a filtering assembly arranged on the insulating support 61, the insulating support 61 being connected to the wall of the nacelle C and being arranged tapering in the direction of flow of the air inside the first cavity C1.

In the process that the outside cooling air is guided to the cabin C by the driving devices 3 of more than two subsystems S, the mixed air after desalination and dehumidification continuously collides with the inner wall of the isolation support 61 to generate resistance, the pressure is gradually reduced, and the flow speed is gradually increased, so that the mixed air is pushed into the filtering component at a high speed. The spacer 61 may be of a parabolic or conical configuration, which is generally preferred for ease of manufacture.

Further, the filter assembly includes a first filter element 621 disposed adjacent to the first cavity C1 and a second filter element 622 disposed adjacent to the second cavity C2, and the filter mesh size of the second filter element 622 is smaller than that of the first filter element 621. The first filter 621 removes large particles such as dust remaining in the air, and the second filter 622 removes remaining salt mist particles having a diameter of, for example, more than 5 μm, thereby further improving the purity of the mixed air.

The filtered air can directly cool the heating components In the cabin C, and enters the inside of the generator M through the filter member F at the air inlet In of the generator M, the filter member F is used for removing the impurities such as dust remaining In the mixed air, and then enters the second pipeline 4 through the air outlet O after absorbing the heat of the heating components such as the stator winding, the stator core, the magnetic steel and the like, wherein a part of the high-temperature air enters the first pipeline 1 to continue the next air cooling cycle, and the other part of the high-temperature air is discharged out of the cabin C.

Referring to fig. 2, in order to enhance the cooling effect on the generator M, each subsystem S further includes a plurality of sub-ducts 41 provided in the nacelle C and communicating with the outside, and the plurality of sub-ducts 41 are disposed at a portion downstream of the filter device 6 of the nacelle C and communicate with the second duct 4 to discharge high-temperature air generated by the generator M to the outside of the nacelle C through the plurality of sub-ducts 41.

Since the generator M may have variations in the manufacturing process, which affect the distribution of the cooling air on the air cooling system within the generator M, in order to maintain the uniformity of the temperature of the generator M in the circumferential direction, the plurality of sub-ducts 41 of the two subsystems S are distributed alternately in the circumferential direction within the nacelle C. For example, the first subsystem S includes 3 sub-pipelines 41 disposed in the nacelle C and communicating with the outside, such as a black pipeline shown in fig. 2, the second subsystem S includes 3 sub-pipelines 41 disposed in the nacelle C and communicating with the outside, such as a white pipeline shown in fig. 2, and the 6 sub-pipelines 41 of the two subsystems S are alternately distributed in the nacelle C along the circumferential direction, so that the uniform stability of heat dissipation of the generator M is maintained, and the operational reliability of the generator M is improved.

Referring to fig. 3, an embodiment of the present invention further provides an air cooling system, which has a similar structure to the air cooling system shown in fig. 1, except that the second ducts 4 of two or more subsystems S are integrally arranged, so that the number of the second ducts 4 and the first circulating fans 42 can be reduced, the manufacturing cost can be reduced, the occupied space of the cabin can be reduced, and the layout is compact. At this time, the high-temperature gas of the generator M in the single second duct 4 is respectively mixed with the first ducts 1 of the two or more subsystems S, and after the outside cold air entering the cabin C from the first ducts 1 is dehumidified and desalted, the air is mixed again, and then the air is filtered and enters the cabin C and the generator M to cool the heat generating components of the cabin C and/or the generator M.

Referring to fig. 4 and 5, an embodiment of the present invention further provides an air cooling system, which has a structure similar to that of the air cooling system shown in fig. 1, except that the generator M is further provided with an auxiliary air outlet a, the air cooling system further includes a third pipeline 7, one end of the third pipeline 7 is connected to the auxiliary air outlet a, and the other end of the third pipeline is communicated with the outside.

Further, a second circulation fan 71 is provided on the third duct 7 to improve the exhaust efficiency of the third duct 7.

The auxiliary air outlet A is used for dividing high-temperature air exhausted from an air outlet of the generator M into two branches: one part of high-temperature air of one branch is mixed with wet and cold air in the first pipeline 1 through the second pipeline 4, and the other part of high-temperature air is discharged out of the cabin C; the other branch is directly discharged outside the cabin C through a third duct 7. The exhaust resistance of the second duct 4 can be reduced relative to the air cooling system shown in figure 1, effectively reducing the power requirements on the first recycle fan 42, while reducing the complexity of the air cooling system.

Alternatively, as shown in fig. 5, the auxiliary air outlet a of the generator M is disposed corresponding to the cabin C, each subsystem S further includes a plurality of sub-ducts 41 disposed in the cabin C and communicating with the outside, and the plurality of sub-ducts 41 communicate with the third duct 7 to discharge the high-temperature air generated by the generator M to the outside of the cabin C through the plurality of sub-ducts 41.

Since the generator M may have variations in the manufacturing process, which affect the distribution of the cooling air on the air cooling system in the generator M, in order to maintain the uniformity of the temperature of the generator M in the circumferential direction, the plurality of sub-ducts 41 of the two or more subsystems S are distributed alternately in the circumferential direction in the nacelle C. Taking two subsystems S as an example, the first subsystem S includes 3 sub-pipelines 41 arranged in the nacelle C and communicated with the outside, such as a black pipeline shown in fig. 2, the second subsystem S includes 3 sub-pipelines 41 arranged in the nacelle C and communicated with the outside, such as a white pipeline shown in fig. 2, and 6 sub-pipelines 41 of the two subsystems S are alternately distributed in the nacelle C along the circumferential direction, so that the uniformity of the temperature of the generator M in the circumferential direction is ensured, and the operational reliability of the generator M is improved.

It is understood that the structure of each subsystem S of the air cooling system provided by the embodiment of the present invention may be different, for example, one subsystem S includes the first pipeline 1, the dehumidifying apparatus 2, the driving device 3, the second pipeline 4 and the filtering apparatus 6, and the other subsystem S includes the first pipeline 1, the dehumidifying apparatus 2, the driving device 3, the second pipeline 4 and the dehumidifying apparatus or other apparatuses, so as to realize different functions.

Referring to fig. 6, an embodiment of the present invention further provides an air cooling system, which is similar to the air cooling system shown in fig. 4, except that the auxiliary air outlet a of the generator M is disposed outside the cabin C, and the second circulating fan 71 is also disposed outside the cabin C, so that a plurality of sub-ducts 41 are omitted, the occupied space of the cabin C is reduced, the layout is more compact and simpler, and the manufacturing cost is reduced.

In addition, an embodiment of the present invention further provides a wind turbine generator system, which includes: a generator M, a nacelle C connected to the generator M, and any of the air cooling systems described above, which is disposed between the nacelle C and an air intake In of the generator M.

As mentioned above, any air cooling system is arranged between the cabin and the air inlet of the generator, and comprises more than two subsystems S which respectively and independently operate, when one subsystem S fails, the operation of the other subsystem S is not influenced, the fault tolerance and the reliability of the air cooling system are improved, the air cooling system is simple and compact in structure, the occupied space of the cabin C is saved, the cost is lower, and the maintainability of the wind generating set is improved.

Referring to fig. 7, an embodiment of the present invention further provides a cooling method of a wind turbine generator set as described above, where the cooling method includes:

step S1: acquiring running instruction information, wherein the running instruction comprises a first instruction and a second instruction;

step S2: and when the first instruction is obtained, simultaneously starting the driving devices 3 of the N subsystems S, wherein N is more than or equal to 2, so as to realize the first function. Optionally, the first function is at least one of cooling, dehumidifying and desalting the wind park.

Step S3: when the second instruction is obtained, the driving devices 3 of the N subsystems S alternately operate for a predetermined time, respectively, to implement the second function. Optionally, the second function is to de-ice the dehumidification device 2 or the like.

The implementation of the first function in step S2 includes:

step S21: simultaneously starting driving equipment 3 of N subsystems S, wherein each subsystem S at least comprises a dehumidifying device 2 which is arranged on the wall of the cabin C and communicated with the cabin C and the driving equipment 3 arranged in the cabin C;

step S22: the outside cooling air enters the cabin C through the dehumidifier 2 under the action of the driving devices 3 of the N subsystems S, mixes with part of the high temperature air discharged from the air outlet O of the generator M, and exchanges heat with the heat generating components of the cabin C and/or the generator M.

The implementation of the second function in step S3 includes:

step S31: it is monitored whether the ambient temperature outside the cabin C is below a predetermined temperature, for example 0 ℃.

Step S32: if yes, starting the driving equipment 3 of the ith subsystem S in the N subsystems S, operating for a preset time, and realizing the deicing of the dehumidifying devices 2 of the other subsystems S in the N subsystems S, wherein i is more than or equal to 1 and is less than N. The predetermined time may be 10 minutes to 30 minutes.

Step S33: and closing the driving equipment 3 of the ith subsystem S, starting the driving equipment 3 of the (i + 1) th subsystem S, and operating for a preset time to realize the deicing of the dehumidifying devices 2 of the rest subsystems S in the N subsystems S.

It will be appreciated that if the ambient temperature outside the nacelle C is higher than a predetermined temperature, the wind turbine generator system may be air-cooled directly without de-icing the dehumidifier 2.

According to the cooling method of the wind generating set, provided by the embodiment of the invention, different functions can be realized according to different received instructions, the functionality of an air cooling system is expanded, and particularly when the environment temperature outside the cabin C is monitored to be lower than the preset temperature, the dehumidifying device 2 is firstly deiced, and then the wind generating set is subjected to air cooling, so that the cooling effect of the wind generating set is improved, and the service life of the wind generating set is prolonged.

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.