DE202023103768U1 - Cooling structure and back displacement detection device for wind turbine spindle - Google Patents

Abstract

Cooling structure, characterized in
in that the cooling structure comprises a gear arrangement (100) which has a shell (101), a main part (102) which is rotatably connected to the shell (101), an upper gear part (103) which is arranged above the main part (102). , a lower gear part (104) which is arranged under the main part (102), a belt component (105) which is driven between the main part (102), the upper gear part (103) and the lower gear part (104), and an electric motor (106), the output of which is firmly connected to the main part (102), wherein the upper gear part (103) and the lower gear part (104) are rotatably connected to the casing (101), and wherein the upper gear part ( 103) and the lower gear part (104) are fittingly connected to the main part (102); and that
the cooling structure comprises a cooling arrangement (200) which comprises a water cooler (201) which is firmly connected to the casing (101) and an air cooler (202) which is firmly connected to the lower transmission part (104).

Description

Technical area

The utility model relates to the technical field of wind energy generation, in particular to a cooling structure and a back displacement detection device for wind turbine spindle.

State of the art

A wind turbine is a tool that converts the mechanical energy generated when the wind turbine rotates into mechanical energy after the wind turbine is rotated by wind. But due to the long working time of the wind turbine during the long work conversion process, the heat on the surface is very high and very susceptible to damage to the generator.

The existing cooling structure is generally to install a cooling plate in front of the heating element and then cool the cooling plate, but some of the current wind turbines have unsatisfactory cooling effects due to their own design characteristics, and the wind turbine spindle often moves backward due to too long working time, and the distance of this back shift is very small, and the workers often cause great losses because it is difficult to detect the distance of the offset.

Disclosure of the utility model

The purpose of this section is to outline some aspects of embodiments of the present utility model and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section and in the summary description and utility model designation of the present application in order to avoid obscuring the purpose of this section, summary description and utility model designation, and such simplifications or omissions cannot be used to limit the scope of the present utility model.

In view of the problem that the cooling effect is not ideal in the above or prior art, the utility model is proposed.

The present utility model is based on the task of providing a cooling structure.

In order to solve the above technical problems, the utility model provides the following technical solutions: A cooling structure includes a gear assembly comprising a shell, a main part rotatably connected to the shell, an upper gear part disposed above the main part a lower gear part disposed below the main part, a belt member drivenly arranged between the main part, the upper gear part and the lower gear part, and an electric motor whose output is fixedly connected to the main part, the upper gear part and the lower gear part is rotatably connected to the shell, and wherein the upper gear part and the lower gear part are fittingly connected to the main part; and the cooling structure includes a cooling arrangement that includes a water cooler fixedly connected to the shell and an air cooler fixedly connected to the lower transmission part.

According to an advantageous embodiment of the present utility model, it is provided that the main part comprises a drive shaft which is rotatably connected to the casing, a first central gear which is fixedly connected to the drive shaft, a second central gear which is arranged on one side of the first central gear, remote from the casing, a center bevel gear disposed on an end of the drive shaft remote from the casing, and a pressure wrench disposed above the center bevel gear; wherein the second center gear and the center bevel gear are firmly connected to the drive shaft.

According to an advantageous embodiment of the present utility model, it is provided that the pressure wrench has an upper bevel gear which is in engagement with the middle bevel gear, a fixing rod which is firmly connected between the casing and the upper bevel gear, a control push shaft which is firmly connected to the top of the upper bevel gear, a control block disposed between the upper bevel gear and a projection at the tip of the control push shaft, and a push block disposed on a side of the control block; wherein the control push shaft is slidably connected to the control block.

According to an advantageous embodiment of the present utility model, it is provided that the upper gear part has an upper shaft which is rotatably connected to the casing, an upper gear which is arranged on a central portion of the upper shaft, and an upper key which is attached to one side of the upper shaft located away from the casing; where the top button is a half gear on one end the upper shaft remote from the shell, an upper stop block engaged with the half gear, and a protective cover slidably connected to the upper stop block; where the gear and the upper button are firmly connected to the upper shaft.

According to an advantageous embodiment of the present utility model, it is provided that the lower gear part comprises a lower shaft rotatably connected to the casing and a lower gear arranged on a central portion of the lower shaft; wherein the belt member includes an upper belt and a lower belt, the upper belt fittingly connected between the upper gear and the second center gear, the lower belt fittingly connected between the lower gear and the first center gear; where the lower gear is firmly connected to the lower shaft.

According to an advantageous embodiment of the present utility model, it is provided that the water cooler has a housing that is firmly connected to the casing, a coupling that is firmly connected to the housing, a housing cover that is arranged at one end of the coupling, which is away from located remotely from the housing and comprising a sprinkler disposed above the bottom of the housing; wherein the clutch includes a fixed block fixedly connected to the housing and the housing cover and a rotation shaft disposed within the fixed block; wherein the rotating shaft is rotatably connected to the fixed block, wherein the housing cover is fixedly connected to the upper stop block.

According to an advantageous embodiment of the present utility model, it is provided that the sprinkler has a push rod which is fixedly connected to the push block, a lower pressure plate which is arranged at an end of the push rod which is remote from the push block, a spray housing which is sliding connected to the push rod, an outlet valve disposed on the lower pressure plate, and an inlet valve rotatably connected to an inside bottom of the spray housing; wherein the lower pressure plate is sealingly and slidably connected to an inside of the spray housing; wherein the exhaust valve is rotatably connected to the lower pressure plate.

The present utility model has the following advantageous aspects: The utility model provides a stable force for the gear assembly by adjusting the electric motor. By providing the gear arrangement, the cooling arrangement can collect rainwater in the water tank when it rains, and the sprinkler sprays water on the cooling plate of the wind turbine to achieve water cooling, while the air cooler rotates to achieve dual cooling of air cooling and water cooling .

In view of the problem that it is difficult to detect the distance of the spindle offset in the above or prior art, the utility model is proposed.

The present utility model is based on the object of providing a back displacement detection device for wind turbine spindles.

In order to solve the above technical problems, the utility model provides the following technical solutions: A back displacement detection device for wind turbine spindle includes a cooling structure and a detection assembly, the detection assembly including a gear box disposed under the radiator and a support group disposed under the gear box is, as well as a displacement sensor arranged between the support group.

According to an advantageous embodiment of the present utility model, it is provided that the support group comprises an elastic support block which is arranged under the gear box and a torque arm which is fixedly connected under the gear box, the elastic support block being fixedly connected to the gear box, wherein the torque arm is arranged between the two groups of the elastic support block.

According to an advantageous embodiment of the present utility model, it is provided that the displacement sensor is arranged within the elastic support block and the torque arm and is firmly connected to the inside of the elastic support block and the torque arm.

The present utility model has the following advantageous aspects: By providing the detection arrangement, the utility model allows the worker to control the change in the distance between the torque arm of the gear box and the front and rear elastic supports to determine whether the spindle bearing needs to be repaired , effectively improving the reliability of the wind turbine equipment and reducing the loss.

Short description of the characters

• 1 zeigt eine schematische Strukturansicht einer Kühlstruktur.
• 2 zeigt eine schematische Strukturansicht der Getriebeanordnung und des Luftkühlers in 1.
• 3 zeigt eine schematische Strukturansicht der Getriebeanordnung in 2.
• 4 zeigt eine schematische Strukturansicht des Druckschlüssels in 3.
• 5 zeigt eine schematische Strukturansicht des Riemenbauteils in 1.
• 6 zeigt eine schematische Strukturansicht der Obertaste in 5.
• 7 zeigt eine schematische Strukturansicht der Kühlanordnung in 1.
• 8 zeigt eine schematische Strukturansicht eines Teils A in 7.
• 9 zeigt eine schematische Strukturansicht des Sprinklers in 7.
• 10 zeigt eine schematische Strukturansicht eine Rückverschiebungsdetektionsvorrichtung für Windkraftanlagenspindel.

In order to explain the solutions of the exemplary embodiments of the present utility model more clearly, the drawings that are required to describe the exemplary embodiments are briefly presented below. Obviously, the drawings in the following description only represent a few exemplary embodiments of the present utility model. The person skilled in the art can also obtain further drawings based on these drawings without any inventive step. In the figures:

• 1 shows a schematic structural view of a cooling structure.
• 2 shows a schematic structural view of the transmission arrangement and the air cooler in 1 .
• 3 shows a schematic structural view of the gear arrangement in 2 .
• 4 shows a schematic structural view of the pressure key in 3 .
• 5 shows a schematic structural view of the belt component in 1 .
• 6 shows a schematic structural view of the top button in 5 .
• 7 shows a schematic structural view of the cooling arrangement in 1 .
• 8th shows a schematic structural view of a part A in 7 .
• 9 shows a schematic structural view of the sprinkler in 7 .
• 10 shows a schematic structural view of a back displacement detection device for wind turbine spindle.

Detailed Embodiments

In order to make the above-mentioned objects, features and advantages of the present utility model more understandable, the specific embodiments of the present utility model will be described in detail below with reference to the accompanying drawings for description.

The description below explains many specific details to facilitate a complete understanding of the utility model. However, the present utility model may be embodied in many ways other than the manner described herein. The person skilled in the art can make similar extensions without violating the concept of the present utility model. Therefore, the present utility model is not limited to the specific embodiments disclosed below.

Second, by “an embodiment” or “embodiment” herein is meant a particular feature, structure or property that may be included in at least one implementation of the utility model. The words “in one embodiment” appearing in various places throughout this specification do not all refer to the same embodiment, nor do they represent separate or selective embodiments that are mutually exclusive.

Example 1

With reference to the 1 until 3 the first embodiment of the utility model provides a cooling structure that includes a gear assembly 100 and a cooling assembly 200, wherein the cooling assembly 200 is arranged on one side of the gear assembly 100. The provision of the gear assembly 100 serves to control the operation of the cooling assembly 200; wherein the gear assembly 100 comprises a casing 101, a main part 102 rotatably connected to the casing 101, an upper gear part 103 disposed above the main part 102, a lower gear part 104 disposed below the main part 102, a belt component 105 , which is driven between the main part 102, the upper gear part 103 and the lower gear part 104, and an electric motor 106, the output of which is fixedly connected to the main part 102, wherein the upper gear part 103 and the lower gear part 104 are rotatable with the Shell 101 are connected, and wherein the upper gear part 103 and the lower gear part 104 are fittingly connected to the main part 102.

Specifically, the main part 102 includes a drive shaft 102a rotatably connected to the shell 101, a first center gear 102b fixedly connected to the drive shaft 102a, a second center gear 102c disposed on a side of the first center gear 102b, which is from the shell 101, a center bevel gear 102d disposed on an end of the drive shaft 102a remote from the shell 101, and a pressure wrench 102e disposed above the center bevel gear 102d, the second center gear 102c and the center bevel gear 102d is fixedly connected to the drive shaft 102a; wherein the drive shaft 102a is fixedly connected to the output shaft of the electric motor 106 near one end of the shell 101, thereby providing a stable force for rotation of the drive shaft 102a.

Specifically, the pressure wrench 102e includes an upper bevel gear 102e-1 engaged with the middle bevel gear 102d, a fixing rod 102e-2 fixedly connected between the shell 101 and the upper bevel gear 102e-1, a control push shaft 102e-3, which is fixedly connected to the top of the upper bevel gear 102e-1, a control block 102e-4 which is arranged between the upper bevel gear 102e-1 and a projection at the tip of the control push shaft 102e-3, and a thrust block 102e-5 which disposed on one side of the control block 102e-4, with the control push shaft 102e-3 slidably connected to the control block 102e-4; there is a groove on the control block 102e-4 that runs through the top and bottom. The upper bevel gear 102e-1 rotates, causing the control push shaft 102e-3 to rotate in the groove on the control block 102e-4 and drive the push block 102e-5 to perform reciprocating motion.

Further, the upper gear member 103 includes an upper shaft 103a rotatably connected to the shell 101, an upper gear 103b disposed on a central portion of the upper shaft 103a, and an upper key 103c attached to a side of the upper shaft 103a is arranged, which is located away from the shell 101; wherein the upper key 103c, a half gear 103c-1 disposed on an end of the upper shaft 103a remote from the shell 101, an upper stop block 103c-2 engaged with the half gear 103c-1, and an protective cover 103c-3 slidably connected to the upper stop block 103c-2; wherein the gear 103b and the upper button 103c are fixedly connected to the upper shaft 103a; wherein the rotation of the upper shaft 103a drives the half gear 103c-1 to move together. At the same time, the upper stop block 103c-2 moves back and forth in the protective cover 103c-3.

Further, the lower gear member 104 includes a lower shaft 104a rotatably connected to the shell 101, and a lower gear 104b disposed on a central portion of the lower shaft 104a; wherein the belt member 105 includes an upper belt 105a and a lower belt 105b, the upper belt 105a fittingly connected between the upper gear 103b and the second center gear 102c, the lower belt 105b fittingly between the lower gear 104b and the first center gear 102b is connected, the lower gear 104b being fixedly connected to the lower shaft 104a; When the drive shaft 102a is moved, the second center gear 102c and the first center gear 102b move together. At the same time, the upper belt 105a rotates in the same direction with the upper gear 103b and the second center gear 102c. The lower belt 105b rotates in the same direction with the lower gear 104b and the first center gear 102b.

During operation, the drive shaft 102a is energized by the output of the electric motor 106 to rotate it on the shell 101. At this time, the thrust block 102e-5 moves with the rotation of the drive shaft 102a and performs a reciprocating feed motion on the upper bevel gear 102e-1; Due to the arrangement of the belt member 105, the upper shaft 103a and the lower shaft 104a also move along with the movement of the drive shaft 102a. The upper stop block 103c-2 also performs an upward reciprocating movement on the inside of the protective cover 103c-3 accompanying the rotation of the upper shaft 103a.

Embodiment 2

With reference to the 1 until 3 It is a second embodiment of the utility model, which is based on the previous embodiment: A cooling arrangement 200 includes a water cooler 201, which is firmly connected to the shell 101, and an air cooler 202, which is firmly connected to the lower gear part 104.

Further, the water cooler 201 includes a housing 201a fixedly connected to the shell 101, a clutch 201b fixedly connected to the housing 201a, a housing cover 201c disposed at an end of the clutch 201b separated from the housing 201a, and a sprinkler 201d disposed above the bottom of the housing 201a, with the top of the housing 201a and the housing cover 201c exposed outside the electric generator cabin; wherein the clutch 201b includes a fixed block 201b-1 fixedly connected to the housing 201a and the housing cover 201c, and a rotating shaft 201b-2 disposed within the fixed block 201b-1, the rotating shaft 201b-2 being rotatable with connected to fixed block 201b-1; wherein the bottom of the part of the housing cover 201c protruding from the housing 201a is firmly connected to the upper stop block 103c-2. Therefore, when the upper stop block 103c-2 is pushed upward, the housing lid 201c will also make an upward movement, so that the garbage filtered by the housing lid can be cleaned regularly while driving away the birds.

Further, the sprinkler 201d includes a push rod 201d-1 fixedly connected to the push block 102e-5, a lower pressure plate 201d-2 disposed at an end of the push rod 201d-1 remote from the push block 102e-5 a spray housing 201d-3 slidably connected to the push rod 201d-1, an exhaust valve 201d-4 disposed on the lower pressure plate 201d-2, and an inlet valve 201d-5 rotatably connected to an inside bottom of the Spray housing 201d-3 is connected; wherein the air cooler 202 includes a restriction block 202a disposed on one end of the lower shaft 104a and fan blades 201d disposed on a smooth side of the restriction block 202a, the lower pressure plate 201d-2 sealingly and slidingly with an inside of the Spray housing 201d-3 is connected, with the outlet valve 201d-4 rotatably connected to the lower pressure plate 201d-2, with the limit block 202a fixedly connected to the lower shaft 104a. By pushing in the push rod 201d-1, the outlet valve 201d-4 is opened and the inlet valve 201d-5 is closed, thereby completely draining the water in the spray housing 201d-3. Pulling out the push rod 201d-1 closes the outlet valve 201d-4 and opens the inlet valve 201d-5, filling the spray housing 201d-3 with water.

During operation, the top of the housing 201a and the housing cover 201c are exposed outside the cabin of the electric generator. By firmly connecting the housing cover 201c to the upper stop block 103c-2, the housing cover 201c moves upwards together with the rotation of the upper shaft 103a. The sprinkler 201d periodically sprays water on the surface of the heat sink according to the movement of the drive shaft 102a. At the same time, the fan blades 2020b rotate with the rotation of the lower shaft 104a to provide dual cooling by air and water cooling.

Example 3

With reference to 4 until 5 This represents the third exemplary embodiment of the present utility model, which is based on the first two exemplary embodiments. This embodiment provides a wind turbine spindle back displacement detection device comprising a cooling structure and a detection assembly 300, the detection assembly 300 including a gear box 301 disposed under the water cooler 201 and a support group 302 disposed under the gear box 301, and a displacement sensor 303, which is arranged between the support group 302.

Further, the support group 302 includes an elastic support block 302-1 disposed under the gear box 301 and a torque arm 302-2 fixedly connected under the gear box 301, the elastic support block 302-1 being fixedly connected to the gear box 301 , wherein the torque arm 302-2 is disposed between the two groups of the elastic support block 302-1. When the wind turbine spindle is displaced rearward, the distance between the gear box torque arm 302-2 and the front and rear elastic support blocks 302-1 changes. This distance allows personnel to assess whether maintenance on the wind turbine spindle is required.

Furthermore, it is provided that the displacement sensor 303 is arranged within the elastic support block 302-1 and the torque arm 302-2 and is firmly connected to the inside of the elastic support block 302-1 and the torque arm 302-2. In actual application, the displacement sensor 303 is connected to the control system or the on-site alarm system to enable easy alarming. For example, if the normal distance between the torque arm of the gear box and the front and rear elastic support blocks is 10 mm, the displacement sensor 303 sends an alarm signal to the control system or the alarm system when the distance between the torque arm 302-2 of the gear box and the front and rear elastic support blocks 302-1 is 7 mm. This encourages workers to conduct a comprehensive inspection regarding lubrication, vibration and other aspects. When the distance between the torque arm 302-2 of the gear box and the front and rear elastic support blocks 302-1 is 3 mm, the displacement sensor 303 sends an emergency shutdown signal to the control system or the alarm system to prompt the workers to replace the spindle bearings. This effectively improves the reliability of wind turbine equipment and reduces losses.

During operation, the feedback data from the displacement sensor 303 allows workers to detect the distance between the gear box torque arm and the front and rear elastic support blocks in real time. This makes it possible to assess whether a displacement of the electric generator spindle has occurred and whether repair is required.

In summary, the electric motor 106 is first switched on in order to switch it off gear to deliver the driving force to the drive shaft 102a. The rotation of the drive shaft 102a drives the pusher block 102e-5 in a reciprocating forward motion and at the same time, the pusher block 102e-5 moves the sprinkler 201d to spray water onto the heat sink in a timed manner. At this time, the upper shaft 103a rotates due to the arrangement of the belt member 105 and at the same time moves the upper stop block 103c-2 to rotate the housing cover 201c upward. The lower shaft 104a also moves with the movement of the drive shaft 102a and at the same time the fan blades 2020b rotates with the rotation of the lower shaft 104a. This achieves double cooling of the electrical generator through air cooling and water cooling. By providing a displacement sensor 303, personnel can obtain real-time data about the displacement of the electric generator spindle. This improves the reliability of the wind turbine and reduces losses.

It is important to note that the construction and arrangement of the present application, shown in several different exemplary embodiments, is only exemplary. Although only a few embodiments are described in detail in this disclosure, the viewer should readily understand that many modifications are possible without substantially departing from the novel teachings and advantages of the subject matter described in the application (e.g., size, scale, Structure, shape and proportion of the various elements as well as parameter values (e.g. temperature, pressure, etc.), installation arrangement, material use, color, change of direction, etc.). For example, an element shown as an integral form may consist of a plurality of sections or elements, the position of the element may be reversed or otherwise changed, and the type or number or position of the discrete element may be altered or changed. Therefore, all such modifications are intended to be included within the scope of the present invention. The order or sequence of a process or method step may be changed or rearranged according to an alternative implementation. In the claims, each "device plus function" clause aims to cover the structure described in this document that performs the function, and not only the structural equivalence, but also the equivalent structure. Without departing from the scope of the utility model, other substitutions, modifications, changes and omissions may be made in the design, operation and arrangement of the exemplary embodiment. The utility model is therefore not limited to specific embodiments, but extends to a variety of modifications that still fall within the scope of the appended claims.

In addition, in order to provide a brief description of the exemplary embodiment, not all features of the actual embodiment can be described (i.e., those features that are not associated with the currently considered optimal mode of execution of the utility model, or those features that are not consistent with the implementation of the utility model).

It should be understood that during the development of an actual implementation, such as in an engineering or design project, a large number of specific implementation decisions may be made. Such development efforts may be complex and time-consuming, but for ordinary engineers benefiting from this disclosure, not too much experimentation will be required and the development effort will be routine design, manufacturing, and production work.

It should be noted that the above embodiments only serve to illustrate the technical solutions of the present utility model and not to limit them. Although the present utility model has been described in detail with reference to the preferred embodiments, one of ordinary skill in the art should understand that modifications or equivalent substitutions may be made to the technical solutions of the present utility model, all of which should be included within the scope of the claims of the present utility model. without deviating from the spirit and scope of the technical solutions of the present utility model.

Claims (10)

Cooling structure, characterized in that the cooling structure comprises a gear assembly (100) comprising a shell (101), a main part (102) rotatably connected to the shell (101), an upper gear part (103) above the main part (102) is arranged, a lower gear part (104) which is arranged under the main part (102), a belt component (105) which is driven between the main part (102), the upper gear part (103) and the lower gear part (104 ) is arranged, and an electric motor (106), the output of which is firmly connected to the main part (102), wherein the upper gear part (103) and the lower gear part (104) are rotatably connected to the casing (101), and whereby the upper gear part (103) and the lower gear part (104) is fittingly connected to the main part (102); and that the cooling structure comprises a cooling arrangement (200) which includes a water cooler (201) which is firmly connected to the shell (101) and an air cooler (202) which is firmly connected to the lower gear part (104). cooling structure Claim 1 , characterized in that the main part (102) has a drive shaft (102a) which is rotatably connected to the casing (101), a first central gear (102b) which is fixedly connected to the drive shaft (102a), a second central gear (102c ), which is disposed on a side of the first center gear (102b) remote from the casing (101), a center bevel gear (102d) disposed on an end of the drive shaft (102a) which is away from the casing (101) is located remotely and includes a pressure wrench (102e) disposed above the center bevel gear (102d); wherein the second center gear (102c) and the center bevel gear (102d) are firmly connected to the drive shaft (102a). cooling structure Claim 2 , characterized in that the pressure wrench (102e) has an upper bevel gear (102e-1) which is in mesh with the middle bevel gear (102d), a fixing rod (102e-2) which is fixed between the casing (101) and the upper bevel gear (102e-1), a control push shaft (102e-3) which is firmly connected to the top of the upper bevel gear (102e-1), a control block (102e-4) which is connected between the upper bevel gear (102e-1 ) and a projection disposed at the tip of the control push shaft (102e-3), and a push block (102e-5) disposed on a side of the control block (102e-4); wherein the control push shaft (102e-3) is slidably connected to the control block (102e-4). cooling structure Claim 3 , characterized in that the upper gear part (103) includes an upper shaft (103a) rotatably connected to the casing (101), an upper gear (103b) disposed on a central portion of the upper shaft (103a), and a top button (103c) disposed on a side of the top shaft (103a) remote from the case (101); wherein the upper button (103c) has a half gear (103c-1) disposed on an end of the upper shaft (103a) remote from the shell (101), an upper stop block (103c-2) connected to the half gear (103c-1) meshes and includes a protective cover (103c-3) slidably connected to the upper stop block (103c-2); wherein the gear (103b) and the upper button (103c) are firmly connected to the upper shaft (103a). cooling structure Claim 4 , characterized in that the lower gear part (104) includes a lower shaft (104a) rotatably connected to the shell (101), and a lower gear (104b) disposed on a central portion of the lower shaft (104a). , includes; wherein the belt member (105) comprises an upper belt (105a) and a lower belt (105b), the upper belt (105a) being fittingly connected between the upper gear (103b) and the second center gear (102c), the lower belt (105b) is fittingly connected between the lower gear (104b) and the first center gear (102b); wherein the lower gear (104b) is firmly connected to the lower shaft (104a). Cooling structure according to one of the Claims 1 until 5 , characterized in that the water cooler (201) has a housing (201a), which is firmly connected to the casing (101), a coupling (201b), which is firmly connected to the housing (201a), a housing cover (201c), disposed at an end of the coupling (201b) remote from the housing (201a) and comprising a sprinkler (201d) disposed above the bottom of the housing (201a); wherein the clutch (201b) includes a fixed block (201b-1) fixedly connected to the housing (201a) and the housing cover (201c), and a rotating shaft (201b-2) disposed within the fixed block (201b-1). is, includes; wherein the rotating shaft (201b-2) is rotatably connected to the fixed block (201b-1); wherein the housing cover (201c) is firmly connected to the upper stop block (103c-2). cooling structure Claim 6 , characterized in that the sprinkler (201d) has a push rod (201d-1) which is firmly connected to the push block (102e-5), a lower pressure plate (201d-2) which is attached to one end of the push rod (201d-1 ) is arranged, which is located away from the push block (102e-5), a spray housing (201d-3) which is slidably connected to the push rod (201d-1), an outlet valve (201d-4) which is located on the lower Pressure plate (201d-2) is arranged, and comprises an inlet valve (201d-5) rotatably connected to an inside bottom of the spray housing (201d-3); wherein the air cooler (202) includes a restriction block (202a) disposed on one end of the lower shaft (104a), and fan blades (2020b) disposed on a smooth side of the restriction block (202a); wherein the lower pressure plate (201d-2) is sealingly and slidably connected to an inside of the spray housing (201d-3); wherein the exhaust valve (201d-4) is rotatably connected to the lower pressure plate (201d-2); where the limiting block (202a) is firmly connected to the lower shaft (104a). Back displacement detection device for wind turbine spindle, characterized in that it has a cooling structure according to one of Claims 1 until 7 and a detection assembly (300) comprising a gearbox (301) disposed under the radiator (201) and a support group (302) disposed under the gearbox (301), and a displacement sensor (303) which is arranged between the support group (302). cooling structure Claim 8 , characterized in that the support group (302) comprises an elastic support block (302-1) arranged under the gear box (301) and a torque arm (302-2) fixedly connected under the gear box (301). ; wherein the elastic support block (302-1) is fixedly connected to the gear box (301); wherein the torque arm (302-2) is disposed between the two groups of the elastic support block (302-1). cooling structure Claim 9 , characterized in that the displacement sensor (303) is arranged inside the elastic support block (302-1) and the torque arm (302-2) and fixed to the inside of the elastic support block (302-1) and the torque arm (302-2) connected is.

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