CN117956759A - Converter water-cooled tube connecting device for offshore wind power - Google Patents

Abstract

The invention relates to the technical field of offshore wind power equipment, in particular to a water cooling pipe connecting device of a current transformer for offshore wind power, which comprises a water cooling mechanism, a water cooling mechanism and a water cooling device, wherein the water cooling mechanism comprises a radiator and a cooling pipe connected to the radiator; the installation mechanism comprises a first connector arranged on the cooling liquid pipeline, a second connector connected with the first connector, a threaded sleeve arranged on the second connector, a fixing component arranged on the first connector, a pressing component arranged on the fixing component and a rotating component arranged on the pressing component, wherein the first rotating block and the second rotating block can rotate through simple stirring actions through the rotating component and the pressing component, and a clamping plate can be clamped with the threaded sleeve in the rotating process, so that the first connector and the second connector can be connected together quickly, tool installation can be avoided in a limited space, and the installation efficiency is improved.

Description

Converter water-cooled tube connecting device for offshore wind power

Technical Field

The invention relates to the technical field of offshore wind power equipment, in particular to a water-cooled tube connecting device of a converter for offshore wind power.

Background

Wind energy is taken as a harmless renewable energy source, and is increasingly paid attention to by people, with the development of scientific technology, the installation capacity of a wind turbine is gradually increased, a wind turbine tower is also increased, the current latest wind turbine is more than 10MW, the height of the tower is more than 120 m, the fault condition of the wind turbine is comprehensively synthesized, and the fault occurrence probability of a wind turbine converter is high, so that the wind turbine is changed from an early single converter into a current double converter.

The double converters are generally located in a fan cabin, and the cabin is provided with equipment with severe heat such as a gear box and a generator, so that water cooling equipment is generally arranged, the space in the cabin is limited, the influence on daily maintenance work is small, but when the pipelines in the water cooling equipment are maintained, particularly when the pipelines are maintained, the two pipelines are connected together by using a connecting piece when the pipelines are connected, tools are needed to be used when the connecting piece is screwed, but the space is not large, and when the tools are used, only a little screwing is needed, so that the working efficiency is reduced.

Disclosure of Invention

The present invention has been made in view of the above or the problems in the prior art that two pipes are connected together by a connecting member when the pipes are connected, and a tool is used when the connecting member is screwed, but the space is not large, and only a little screwing is performed when the tool is used, thereby causing a decrease in working efficiency.

Therefore, the invention aims to provide a water-cooled pipe connecting device of a converter for offshore wind power.

In order to solve the technical problems, the invention provides the following technical scheme: the water cooling pipe connecting device for the converter for the offshore wind power comprises a water cooling mechanism, a water cooling pipe and a water cooling pipe, wherein the water cooling mechanism comprises a radiator and a cooling pipe connected to the radiator;

The mounting mechanism comprises a first connector arranged on the cooling liquid pipeline, a second connector connected to the first connector, a threaded sleeve arranged on the second connector, a fixing assembly arranged on the first connector, a pressing assembly arranged on the fixing assembly and a rotating assembly arranged on the pressing assembly.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the first connector comprises a connecting ring, a first chute arranged on the connecting ring, an inserting hole formed in the first chute, a baffle arranged on the first chute, a second chute connected on the first chute, and a limit groove formed in the second chute.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the fixing component comprises a cylinder, an annular groove formed in the cylinder, a clamping plate arranged on the cylinder, a connecting ball fixed on the clamping plate and a sawtooth groove arranged on the clamping plate.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the pressing assembly comprises a connecting cylinder, a connecting block arranged on the connecting cylinder, a moving hole arranged on the connecting cylinder, a connecting groove arranged on the moving hole, a pushing piece arranged on the connecting groove and a linkage piece arranged on the connecting cylinder.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the pushing piece comprises a first pushing plate, a second pushing plate, a triangular groove arranged on the first pushing plate and the second pushing plate, and a first bonding surface and a second bonding surface arranged on the triangular groove.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the first pushing plate comprises a plate body, an arc-shaped protruding block is arranged on the plate body, a first abutting surface is arranged on the plate body, and a limiting block is arranged on the plate body.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the linkage includes a first spring sleeve, a compression spring coupled to the first spring sleeve, and a second spring sleeve coupled to the compression spring.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the first spring sleeve comprises a cylinder body, wherein a first contact surface and a second contact surface connected to the first contact surface are arranged on the cylinder body.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the rotary assembly comprises a first rotary block, a second abutting surface is arranged on the first rotary block, a mounting hole is formed in the first rotary block, a connecting surface is arranged on the first rotary block, a first poking piece is arranged on the first rotary block, and the second rotary block is connected to the first rotary block.

As a preferable scheme of the water-cooled tube connecting device of the converter for offshore wind power, the invention comprises the following steps: the second rotating block comprises a block body, a third abutting surface is arranged on the block body, a second poking piece is arranged on the block body, and a rotating surface is arranged on the block body.

The water cooling pipe connecting device for the converter for offshore wind power has the beneficial effects that: according to the invention, the first connector and the second connector are arranged on the cooling liquid pipe, the connecting ring is arranged on the first connector, the clamping plate is connected to the outer wall of the connecting ring, the clamping plate is provided with the saw tooth groove, the second connector is provided with the threaded sleeve, when the first shifting piece and the second shifting piece are shifted, the first rotating block and the second rotating block rotate, the first pushing plate and the second pushing plate are driven to move in the moving hole when rotating, and as one ends of the first pushing plate and the second pushing plate are provided with the arc-shaped protruding blocks, the arc-shaped protruding blocks are matched with the annular grooves on the cylinder, so that the clamping plate can shrink inwards under the action of the first pushing plate and the second pushing plate, and the saw tooth groove can be clamped on the threaded sleeve in the shrinking process, so that the first connector and the second connector are fixed together, and therefore, the screwing and fixing work of a tool is omitted in a limited space is achieved, and the working efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is an overall schematic diagram of a water-cooled tube connection device of a converter for offshore wind power.

Fig. 2 is a schematic structural diagram of a first rotary block and a second rotary block of a water-cooled tube connecting device of a converter for offshore wind power.

Fig. 3 is a schematic structural view of a mounting mechanism of a water-cooled tube connecting device of a converter for offshore wind power.

Fig. 4 is a schematic structural diagram of a fixing assembly of a water-cooled tube connecting device of a converter for offshore wind power.

Fig. 5 is a schematic structural diagram of a pressing assembly of the water-cooled tube connecting device of the converter for offshore wind power.

FIG. 6 is a schematic view of a connection ring of a water-cooled tube connection device of a current transformer for offshore wind power.

Fig. 7 is a schematic diagram of a rotating assembly structure of a water-cooled tube connecting device of a converter for offshore wind power.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

In the embodiment 1, referring to fig. 1 to 3, as a first embodiment of the present invention, the embodiment provides a water cooling pipe connection device for a current transformer for offshore wind power, which includes a water cooling mechanism 100, including a radiator 101, wherein the radiator 101 is installed together with a double current transformer, since the probability of occurrence of a fan current transformer fault is high, after a single current transformer fails, other devices cannot operate, and meanwhile, power generation is affected, and a large economic loss is caused, so that the single current transformer adopted in the fan becomes a double current transformer, the double current transformer can ensure that when one current transformer fails, the other current transformer can continue to generate power, thereby greatly improving economic benefit, and in the process of operating the double current transformer, the double current transformer is easy to work due to serious heat generation, the radiator 101 is required to perform heat dissipation, the cooling liquid pipe 102 connected to the radiator 101 is connected to the radiator 101, and the circulation of the cooling liquid can be realized through the cooling liquid pipe 102;

The installation mechanism 200 comprises a first connector 201 arranged on the coolant pipeline 102, the first connector 201 is in threaded connection with the coolant pipeline 102, a second connector 202 connected to the first connector 201, the second connector 202 is fixed with the first connector 201 through a fixing component 204, a threaded sleeve 203 arranged on the second connector 202 is fixed at one end of the second connector 202 connected with the first connector 201, a fixing component 204 arranged on the first connector 201, a u-shaped component is fixedly connected to the first connector 201, a pressing component 205 arranged on the fixing component 204, a sub-component and a component are fixedly connected to the outer wall of the fixing component, and a rotating component 206 arranged on the pressing component 205, wherein the rotating component 206 is fixedly connected to the pressing component 205, and can press the pressing component 205 through the rotating component 206 so as to drive the pressing component 205 to move.

Specifically, the first connector 201 includes a connection ring 201a, the connection ring 201a is fixedly connected to the coolant pipe 102, a first chute 201b is disposed on the connection ring 201a, the first chute 201b is disposed on a top surface of the connection ring 201a, an insertion hole 201c is disposed on the first chute 201b, the insertion hole 201c is disposed at one end of the first chute 201b, two baffles 201d are fixedly disposed on the first chute 201b and the second chute 201e, the baffles 201d are disposed on outer edges of the first chute 201b and the second chute 201e, the two baffles 201d are symmetrically disposed, a certain gap is reserved between the two baffles 201d, the fixing assembly 204 can be limited by the baffles 201d, a second chute 201e is connected to the first chute 201b, the first chute 201b is connected to the second chute 201e in an L shape, and a limit groove 201f is disposed at an end of the second chute 201e, and a limit groove 201f is disposed at an end of the limit groove 201 f.

Further, the fixing assembly 204 includes a cylinder 204a, the cylinder 204a is fixedly connected to the outer wall of the connection ring 201a, an annular groove 204b is formed in the outer wall of the cylinder 204a, the annular groove 204b is formed in the outer wall of the cylinder 204a, a clamping plate 204c is arranged on the cylinder 204a, the clamping plates 204c are annularly fixed to the inner wall of the cylinder 204a, certain gaps exist between the clamping plates 204c, bottoms of the clamping plates 204c are connected together, a connection ball 204d is fixed to the clamping plates 204c, the connection ball 204d is fixedly connected to the bottom of the clamping plates 204c through a cylinder, the diameter of the connection ball 204d is smaller than the diameter of the insertion hole 201c, the diameter of the cylinder is smaller than the gap between the two baffles 201d, and a sawtooth groove 204e is formed in the clamping plate 204c, the sawtooth groove 204e is formed in one side of the clamping plate 204c, and the sawtooth groove 204e is matched with a thread sleeve 203 on the second connector 202.

The operation process comprises the following steps: in offshore wind power equipment, the double converter plays a vital role, because the double converter is installed in the cabin, a plurality of other equipment are arranged in the cabin, the equipment generates heat seriously, the double converter can not work normally, the radiator 101 is required to cool, and the radiator 101 is most importantly cooled through circulation of cooling liquid, so that a cooling liquid pipe is connected to the radiator 101, the radiator 101 and the cooling liquid pipe are installed in the cabin, in the lengthening working process of the original cooling liquid pipe, the radiator 101 and the cooling liquid pipe are connected through a connecting piece, the space is limited in the process of screwing the connecting piece, the installation process is difficult, a connecting ring 201a is fixed at one end of the cooling liquid pipe, then a connecting ball 204d on a clamping plate 204c is clamped in an inserting hole 201c, then the connecting ball 204d is slid into a second sliding groove 201e from a first sliding groove 201b, then the connecting ball 204d is clamped on a limiting groove 201f, accordingly, the cylinder 204a and the clamping plate 204c are fixed on the connecting ring 201a, then the rotating component 206 is rotated, the rotating component 205 is clamped, the rotating component 205 is pressed against the connecting ring 201c, and then the clamping plate 204c is pressed against the first connecting groove and the connecting ring and the clamping plate 204c is pressed against the first connecting groove.

In embodiment 2, referring to fig. 3 to 6, unlike the previous embodiment, the pressing assembly 205 includes a connecting cylinder 205a, the connecting cylinder 205a is screwed on the outer wall of the cylinder 204a, a connection block 205b disposed on the connecting cylinder 205a, the connection block 205b is fixed on the outer wall of the connecting cylinder 205a, two connection blocks 205b are symmetrically disposed on the outer wall of the connecting cylinder 205a, a moving hole 205c disposed on the connecting cylinder 205a, the moving hole 205c is disposed inside the connecting cylinder 205a, and the moving hole 205c is symmetrically disposed, a connecting groove 205d disposed on the moving hole 205c, the connecting groove 205d is disposed inside the connecting cylinder 205a and penetrates through the connecting groove 205d, a pushing member 205e disposed on the connecting groove 205d, the pushing member 205e is movably connected in the moving hole 205c, and a linkage member 205f disposed on the connecting cylinder 205a is movably connected in the connecting groove 205d, and the linkage member 205f is driven by the pushing member 205 f.

Specifically, the pushing member 205e includes a first pushing plate 205e-1 and a second pushing plate 205e-2, the first pushing plate 205e-1 and the second pushing plate 205e-2 are movably symmetrically disposed and connected in the moving hole 205c, a triangular groove 205e-3 disposed on the first pushing plate 205e-1 and the second pushing plate 205e-2, the triangular groove 205e-3 is respectively formed on bottom surfaces of the first pushing plate 205e-1 and the second pushing plate 205e-2, and a first bonding surface 205e-4 and a second bonding surface 205e-5 disposed on the triangular groove 205e-3, and the first bonding surface 205e-4 and the second bonding surface 205e-5 are formed in the triangular groove 205 e-3.

The first pushing plate 205e-1 includes a plate body 205e-1a, an arc-shaped protruding block 205e-1b is disposed on the plate body 205e-1a, the arc-shaped protruding block 205e-1b is fixedly connected to one end of the first pushing plate 205e-1, the arc-shaped protruding block 205e-1b is adapted to the annular groove 204b, a first abutting surface 205e-1c is disposed on the plate body 205e-1a, the first abutting surface 205e-1c is disposed on one end of the first pushing plate 205e-1, which is provided with the arc-shaped protruding block 205e-1b, and a limiting block 205e-1d is disposed on the plate body 205e-1a, and the limiting block 205e-1d is fixed on one sides of the first pushing plate 205e-1 and the second pushing plate 205e-2, so that the first pushing plate 205e-1 and the second pushing plate 205e-2 can be prevented from being offset in the moving process by the limiting block 205e-1 d.

Further, the linkage 205f includes a first spring sleeve 205f-1 slidably coupled within the coupling groove 205d, a compression spring 205f-2 coupled to the first spring sleeve 205f-1, one end of the compression spring 205f-2 fixedly coupled to the bottom of the first spring sleeve 205f-1, the other end fixedly coupled to the second spring sleeve 205f-3, and a second spring sleeve 205f-3 coupled to the compression spring 205f-2, the second spring sleeve 205f-3 slidably coupled within the coupling groove 205 d.

The rest of the structure is the same as in embodiment 1.

The operation process comprises the following steps: in the process of connecting the first connector 201 with the second connector 202, the pushing piece 205e is driven to move by the rotating component 206, at this time, the first pushing plate 205e-1 and the second pushing plate 205e-2 move towards the direction of the cylinder 204a, in the moving process, the first sleeve and the second sleeve move into the connecting groove 205d, at this time, the compression spring 205f-2 is stressed to deform, at the same time, the arc-shaped protruding blocks 205e-1b on the first pushing plate 205e-1 and the second pushing plate 205e-2 are clamped on the annular groove 204b on the cylinder 204a, then the first pushing plate 205e-1 and the second pushing plate 205e-2 continuously move, so as to apply pressure to the cylinder 204a, the cylinder 204a drives the clamping plate 204c to shrink inwards, the sawtooth groove 204e on the threaded sleeve 203, at this time, when the first connector 201 and the second connector 202 need to be disconnected, the rotating component 206 is rotated, the first pushing plate 205e-1 and the second pushing plate 205e-2 are pushed to separate from the first sleeve 204a, the first sleeve 205e-2 is driven to move towards the first sleeve 204c, and the compression plate 204c is released from the first sleeve 204c, and the compression plate 205e can be restored to the position of the first sleeve 204 c.

Embodiment 3, referring to fig. 3 to 7, in a third embodiment of the present invention, unlike the previous embodiment, the first spring sleeve 205f-1 includes a cylinder 205f-1a, a first contact surface 205f-1b is provided on the cylinder 205f-1a, and a second contact surface 205f-1c connected to the first contact surface 205f-1b, the first contact surface 205f-1b and the second contact surface 205f-1c are provided on the other end of the cylinder 205f-1a for mounting the spring, and at the same time, the inclination angle of the first contact surface 205f-1b and the first contact surface 205e-4 is consistent, the inclination angle of the second contact surface 205f-1c and the second contact surface 205e-5 is consistent, the first spring sleeve 205f-1 and the second spring sleeve 205f-3 are symmetrically provided, when the first spring sleeve 205f-1 and the second spring sleeve are inserted into the triangular groove 205e-3, the first contact surface 205f-1b and the first contact surface 205e-4 and the second contact surface 205e-2 are pushed by the first spring sleeve and the second spring sleeve 205 e-2.

Specifically, the rotating assembly 206 includes a first rotating block 206a, the first rotating block 206a is screwed on the connecting block 205b, the first rotating block 206a is provided with a second abutting surface 206b, the second abutting surface 206b is provided on an inner wall of the first rotating block 206a, the second abutting surface 206b is matched with the first abutting surface 205e-1c on the first pushing plate 205e-1, the first rotating block 206a is provided with a mounting hole 206c, the mounting hole 206c is provided on both the first rotating block 206a and the second rotating block 206f, the first rotating block 206a is provided with a connecting surface 206d, the connecting surface 206d is provided on an inner wall of the first rotating block 206a, the first rotating block 206a is provided with a first pulling piece 206e, the first pulling piece 206e is fixedly connected in the mounting hole 206c, and the second rotating block 206f is screwed with the first rotating block 206a through the connecting surface 206 d.

Further, the second rotating block 206f includes a block 206f-1, a third abutting surface 206f-2 is provided on the block 206f-1, a second pulling piece 206f-3 is provided on the block 206f-1, a rotating surface 206f-4 is provided on the block 206f-1, the third abutting surface 206f-2 is provided on an inner wall of the second rotating block 206f, the second pulling piece 206f-3 is fixedly mounted in a mounting hole 206c on the second rotating block 206f, the rotating surface 206f-4 is provided on the inner wall of the second rotating block 206f, and the rotating surface 206f-4 is in threaded connection with the connecting surface 206 d.

The rest of the structure is the same as in embodiment 2.

The operation process comprises the following steps: when the clamping plate 204c needs to be clamped with the threaded sleeve 203, the first shifting piece 206e and the second shifting piece 206f-3 are shifted, the shifting directions of the first shifting piece 206e and the second shifting piece 206f-3 are opposite, the first rotating block 206a is in threaded connection with the first abutting surface 205e-1c on the first pushing plate 205e-1 under the action of the first shifting piece 206e, so that the first pushing plate 205e-1 is driven to move, and similarly, the second pushing plate 205e-2 moves under the action of the third abutting surface, the clamping plate 204c is clamped on the threaded sleeve 203, so that when a coolant pipe is lengthened, the first connecting head 201 and the second connecting head 202 can be connected together without tools, and when the first rotating block 206a and the second rotating block 206f rotate, the first rotating block 206a is in threaded connection with the second rotating block 206f, and simultaneously the first rotating block 206a is in threaded connection with the abutting block 205b, so that the first rotating block 205 a and the second rotating block 205e-2 are synchronously moved.

It is important to note that the construction and arrangement of the application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present application. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present applications. Therefore, the application is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in order to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the invention, or those not associated with practicing the invention).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (10)

1. The utility model provides a marine wind power is with converter water-cooled tube connecting device which characterized in that: comprising the steps of (a) a step of,

A water cooling mechanism (100) comprising a radiator (101), a coolant pipe (102) connected to the radiator (101);

The mounting mechanism (200) comprises a first connector (201) arranged on the coolant pipeline (102), a second connector (202) connected to the first connector (201), a threaded sleeve (203) arranged on the second connector (202), a fixing assembly (204) arranged on the first connector (201), a pressing assembly (205) arranged on the fixing assembly (204) and a rotating assembly (206) arranged on the pressing assembly (205).

2. The offshore wind power converter water cooling pipe connection device according to claim 1, wherein: the first connector (201) comprises a connecting ring (201 a), a first chute (201 b) arranged on the connecting ring (201 a), an insertion hole (201 c) formed in the first chute (201 b), a baffle (201 d) arranged on the first chute (201 b), a second chute (201 e) connected on the first chute (201 b), and a limit groove (201 f) formed in the second chute (201 e).

3. A converter water cooling pipe connection device for offshore wind power according to claim 1 or 2, wherein: the fixing assembly (204) comprises a cylinder (204 a), an annular groove (204 b) formed in the cylinder (204 a), a clamping plate (204 c) arranged on the cylinder (204 a), a connecting ball (204 d) fixed on the clamping plate (204 c), and a sawtooth groove (204 e) arranged on the clamping plate (204 c).

4. A marine wind power converter water cooling pipe connection device as claimed in claim 3, wherein: the pressing assembly (205) comprises a connecting cylinder (205 a), a connecting block (205 b) arranged on the connecting cylinder (205 a), a moving hole (205 c) arranged on the connecting cylinder (205 a), a connecting groove (205 d) arranged on the moving hole (205 c), a pushing piece (205 e) arranged on the connecting groove (205 d) and a linkage piece (205 f) arranged on the connecting cylinder (205 a).

5. The marine wind power converter water cooling pipe connection device according to claim 4, wherein: the pushing piece (205 e) comprises a first pushing plate (205 e-1) and a second pushing plate (205 e-2), a triangular groove (205 e-3) arranged on the first pushing plate (205 e-1) and the second pushing plate (205 e-2), and a first bonding surface (205 e-4) and a second bonding surface (205 e-5) arranged on the triangular groove (205 e-3).

6. The marine wind power converter water cooling pipe connection device according to claim 5, wherein: the first pushing plate (205 e-1) comprises a plate body (205 e-1 a), an arc-shaped protruding block (205 e-1 b) is arranged on the plate body (205 e-1 a), a first abutting surface (205 e-1 c) is arranged on the plate body (205 e-1 a), and a limiting block (205 e-1 d) is arranged on the plate body (205 e-1 a).

7. A converter water cooling pipe connection device for offshore wind power according to claim 5 or 6, wherein: the linkage (205 f) includes a first spring sleeve (205 f-1), a compression spring (205 f-2) coupled to the first spring sleeve (205 f-1), and a second spring sleeve (205 f-3) coupled to the compression spring (205 f-2).

8. The offshore wind power converter water cooling tube connection device of claim 7, wherein: the first spring sleeve (205 f-1) comprises a cylinder (205 f-1 a), wherein a first contact surface (205 f-1 b) and a second contact surface (205 f-1 c) connected to the first contact surface (205 f-1 b) are arranged on the cylinder (205 f-1 a).

9. The offshore wind power converter water cooling tube connection device of claim 8, wherein: the rotating assembly (206) comprises a first rotating block (206 a), a second abutting surface (206 b) is arranged on the first rotating block (206 a), a mounting hole (206 c) is formed in the first rotating block (206 a), a connecting surface (206 d) is arranged on the first rotating block (206 a), a first poking piece (206 e) is arranged on the first rotating block (206 a), and a second rotating block (206 f) connected to the first rotating block (206 a) is connected.

10. The offshore wind power converter water cooling tube connection device of claim 9, wherein: the second rotating block (206 f) comprises a block body (206 f-1), a third abutting surface (206 f-2) is arranged on the block body (206 f-1), a second poking piece (206 f-3) is arranged on the block body (206 f-1), and a rotating surface (206 f-4) is arranged on the block body (206 f-1).