WO2020019810A1

WO2020019810A1 - Carrying frame of testing wave recorder used for wind power generator

Info

Publication number: WO2020019810A1
Application number: PCT/CN2019/085542
Authority: WO
Inventors: 朱洋; 乐丹丹
Original assignee: 南京瑞贻电子科技有限公司
Priority date: 2018-07-27
Filing date: 2019-05-05
Publication date: 2020-01-30
Also published as: CN110196342B; CN109142805B; CN109142805A; CN110196342A

Abstract

A carrying frame of a testing wave recorder used for a wind power generator, comprising a casing (1), an accommodating cavity (102) being provided in the casing (1), a first pressing plate (2) being connected to the bottom wall of the accommodating cavity (102), a first connecting rod (203) being fixedly connected to the bottom of the first pressing plate (2), the first connecting rod (203) being connected to two symmetrical second connecting rods (205) by means of a pin shaft, the second connecting rods (205) being rotatably connected to the inner wall of the casing (1) by means of first supporting seats (2051), one end of each second connecting rod (205) away from the first connecting rod (203) being connected to a third connecting rod (206) by means of a pin shaft, the upper end of the third connecting rod (206) being connected to a first air pressure mechanism, an output end of the first air pressure mechanism being connected to a fourth connecting rod (304), the upper end of the fourth connecting rod (304) being connected to a fifth connecting rod (306) by means of a pin shaft, the fifth connecting rod (306) being rotatably connected to the inner wall of the casing (1) by means of a second supporting seat (3061), and the other end of the fifth connecting rod (306) being connected to a second air pressing mechanism. The carrying frame has a good fixing effect for the wave recorder, thereby avoiding damage to internal parts of the wave recorder during carrying.

Description

Carrying frame of debugging wave recorder for wind generator

Technical field

The utility model relates to the technical field of a wave recorder, in particular to a carrying frame of a wave recorder for debugging a wind turbine.

Background technique

The wave recorder is used in the power system. When the system fails, it can automatically and accurately record the changes of various electrical quantities before and after the failure. Through the analysis and comparison of these electrical quantities, analysis, processing, and analysis of accidents and judgments Whether the protection operates correctly and improves the level of safe operation of the power system plays an important role.

A wind turbine is a device that converts wind energy into electricity. It is mainly composed of blades, generators, mechanical components and electrical components. When performing fault inspection on wind power generation, it is necessary to bring the wave recorder to the location of the wind turbine for inspection. In the process of carrying, if the wave recorder is directly placed in the car, it is easy to damage the internal parts when bumps are encountered at the end of the road. Therefore, in view of this deficiency, we need a carrying frame for debugging the wave recorder for wind turbines to solve this problem. problem.

technical problem

The purpose of this utility model is to solve the deficiencies in the prior art, and proposes a carrying frame of a debug wave recorder for a wind turbine.

Technical solutions

In order to achieve the above purpose, the present invention adopts the following technical solutions:

A carrying frame for a debug wave recorder for a wind generator includes a box body, wherein a cavity is disposed in the box body, a grip is symmetrically connected to a side wall of the box body, and a bottom wall of the placing cavity body is connected to A first pressure plate, a first link is fixedly connected to the bottom of the first pressure plate, the first link is connected with two symmetrical second links through a pin, and the second link is connected with the first support base through The inner wall of the box is rotationally connected. An end of the second link far from the first link is connected with a third link through a pin, and an upper end of the third link is connected with a first air pressure mechanism. The first air pressure mechanism A fourth link is connected to the output end of the fourth link. A fifth link is connected to the upper end of the fourth link through a pin. The fifth link is rotatably connected to the inner wall of the box through a second support base. A second pneumatic mechanism is connected to the other end of the connecting rod.

Preferably, the first air pressure mechanism includes a first sealed housing, a first piston is slidably connected in the first sealed housing, the first piston is fixedly connected to a third connecting rod, and the first sealed housing A fixed seat is fixedly connected to the inner wall of the box, a second piston is slidably connected in the first sealed housing, and an upper end of the second piston is fixedly connected to a fourth link.

Preferably, a third spring is sleeved on the fourth link, and the two ends of the third spring respectively abut against the second piston and the inner wall of the first sealed casing, and a vent valve is connected to the side wall of the first sealed casing. The inner wall of the first sealed housing is symmetrically connected with two stoppers.

Preferably, the second pneumatic mechanism includes a sixth link, one end of the sixth link is rotatably connected to the fifth link through a pin, and the other end of the sixth link is fixedly connected with a second pressure plate. Two second telescopic rods are symmetrically connected to the second pressure plate away from the sixth link. One end of the second telescopic rod away from the second pressure plate is connected to a third pressure plate. The second telescopic rod is sleeved with a first telescopic rod. Four springs, the two ends of the fourth spring respectively abut against the second pressure plate and the third pressure plate, an air bag is connected between the second pressure plate and the third pressure plate, and the air bag is connected with three second sealed shells through a pressure tube, Three of the second sealed housings are equally spaced on the inner wall of the placing cavity. A third piston is slidably connected to the second sealed housing, and a push rod is fixedly connected to the third piston. An arc-shaped pressure plate is connected to one end of the third piston.

Preferably, a rubber pad is connected to an end of the third pressure plate remote from the second pressure plate.

Preferably, a fifth spring is sleeved on the push rod, and both ends of the fifth spring abut against the third piston and the inner wall of the second sealed housing, respectively.

Preferably, a first telescopic rod is symmetrically connected to the bottom of the first pressing plate, the other end of the first telescopic rod is connected to a placing cavity, a first spring is sleeved on the first telescopic rod, and the first The two ends of the spring abut against the first pressure plate and the placing cavity, respectively.

Preferably, the second link is provided with a through slot, and the first link is slidably connected to the through slot through a pin shaft.

Preferably, a second spring is sleeved on the first connecting rod, and the two ends of the second spring respectively abut against the bottom wall of the box body and the first pressing plate.

Beneficial effect

Compared with the prior art, the utility model provides a carrying frame for a debug wave recorder for a wind turbine, which has the following beneficial effects:

1. The carrying frame of the debug wave recorder for the wind turbine generator is placed in the placement cavity, and the bottom of the wave recorder abuts against the first pressure plate, thereby driving the first link to move downward, and then through The two second links drive the third link to move upwards, which in turn drives the two first pneumatic mechanisms to work, and the two first pneumatic mechanisms of the copper drum drive the two fourth links to move upwards. The fifth link rod drives two second air pressure mechanisms to fix the wave recorder. This device has a good effect on the wave recorder and prevents the internal parts of the wave recorder from being damaged during carrying.

2. The carrying frame of the debug wave recorder for a wind turbine includes a first sealed housing through a first pneumatic mechanism, a first piston is slidably connected in the first sealed housing, and the first piston is fixedly connected to the third connecting rod. The first sealed casing passes through the fixing seat and the box body) 1. The inner wall is fixedly connected, and the second piston is slidably connected in the first sealed housing. The upper end of the second piston is fixedly connected to the fourth connecting rod. The upward movement of the third connecting rod drives the first piston to slide in the first sealed housing. , And then drive the second piston to slide in the first sealed housing, and then drive the fourth link to move upward.

3. The carrying frame of the debug wave recorder for the wind generator is sleeved with a third spring through a fourth link, and the two ends of the third spring respectively abut the second piston and the inner wall of the first sealed casing, and the first sealed casing A vent valve is connected to the side wall of the body, and two stoppers are symmetrically connected to the inner wall of the first sealed housing. After use, the first sealed housing is deflated by the vent valve, and the second piston is automatically reset by a third spring. The stop blocks the second piston.

4. The carrying frame of the debug wave recorder for the wind turbine drives the sixth link through the fifth link to move the second pressure plate, and then drives the third pressure plate to press the wave recorder through the second telescopic rod. At the same time, at the same time, the airbag is compressed, and the third piston is driven to slide in the second sealed housing through the pressure tube, and the arc pressure plate is driven to push the rod to fix the recorder.

5. The carrying frame of the debug wave recorder for the wind generator is connected with a rubber pad at the end of the third pressure plate away from the second pressure plate, and the friction between the third pressure plate and the wave recorder is increased by the rubber pad, so that the fixing effect is achieved. better.

6. The carrying frame of the debug wave recorder for the wind turbine is provided with a fifth spring through a push rod, and the two ends of the fifth spring respectively abut the third piston and the inner wall of the second sealed housing. After the use is completed, The fifth piston drives the third piston to automatically reset, thereby facilitating the next installation.

7. The carrying frame of the debug wave recorder for the wind generator is symmetrically connected to the first telescopic rod through the bottom of the first pressure plate, the other end of the first telescopic rod is connected to the placing cavity, and the first telescopic rod is sleeved with the first telescopic rod. A spring. The two ends of the first spring respectively abut against the first pressure plate and the placing cavity, and the buffering effect is provided by the first telescopic rod and the first spring.

8. The carrying frame of the debug wave recorder for the wind turbine is provided with a through slot on the second link, and the first link is slidably connected to the through slot through a pin, so that when the first link moves downward, The second link moves by sliding in the through groove.

9. The carrying frame of the debug wave recorder for the wind turbine is provided with a second spring sleeved on the first link, and the two ends of the second spring respectively abut the bottom wall of the box and the first pressure plate, and the wave recorder is taken out. At the same time, the first pressure plate can be automatically reset by the second spring.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic structural diagram of a carrying frame of a debug wave recorder for a wind turbine according to the present invention;

2 is a schematic structural view of a part A in a carrying block diagram 1 of a debug wave recorder for a wind turbine according to the present invention;

3 is a schematic diagram of a connection structure between a first link and a second link of a carrying frame of a debug wave recorder for a wind turbine according to the present invention;

4 is a schematic structural diagram of part B in a carrying block diagram 1 of a debug wave recorder for a wind turbine proposed by the present utility model;

5 is a structural schematic diagram of a part C in a carrying block diagram 1 of a debug wave recorder for a wind turbine according to the present invention;

FIG. 6 is a schematic structural diagram of a part D in a carrying block diagram 1 of a debug wave recorder for a wind turbine proposed by the present utility model.

In the picture: 1. Box body; 101. Grip; 2. First pressure plate; 201. First telescopic rod; 202. First spring; 203. First link; 204. Second spring; 205. Second connection Lever; 2051, first support seat; 2052, through groove; 206, third connecting rod; 207, first piston; 3, first sealed housing; 301, vent valve; 302, second piston; 303, stopper 304, fourth link; 305, third spring; 306, fifth link; 3061, second support base; 4, sixth link; 401, second pressure plate; 402, second telescopic rod; 403, Fourth spring; 404, third pressure plate; 405, rubber pad; 5, airbag; 501, pressure tube; 6, second sealed housing; 601, third piston; 602, push rod; 603, fifth spring; 604 , Curved pressure plate.

Embodiments of the invention

In the following, the technical solutions in the embodiments of the present invention will be clearly and completely described with reference to the drawings in the embodiments of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, rather than all the implementations. example.

In the description of the present utility model, it should be understood that the terms "up", "down", "front", "rear", "left", "right", "top", "bottom", "inner", The orientation or positional relationship indicated by "outside" and the like is based on the orientation or positional relationship shown in the drawings, and is only for the convenience of describing the utility model and simplified description, and does not indicate or imply that the device or element referred to must have a specific orientation As it is constructed and operated in a specific orientation, it cannot be understood as a limitation on the present invention.

Example 1:

Referring to Figs. 1-3, a carrying frame of a debug wave recorder for a wind generator includes a box body 1, a housing cavity 102 is disposed in the housing body 1, a handle 101 is symmetrically connected to a side wall of the housing body 1, and the cavity is placed. A first pressure plate 2 is connected to the bottom wall of the body 102, and a first link 203 is fixedly connected to the bottom of the first pressure plate 2. The first link 203 is connected with two symmetrical second links 205 and a second link 205 through a pin. The first support base 2051 is rotatably connected to the inner wall of the box body 1. The end of the second link 205 away from the first link 203 is connected to the third link 206 through a pin, and the upper end of the third link 206 is connected to the first air pressure. Mechanism, the output end of the first pneumatic mechanism is connected to a fourth link 304, the upper end of the fourth link 304 is connected to a fifth link 306 through a pin, and the fifth link 306 is connected to the case 1 through the second support base 3061 The inner wall is connected in rotation, and the other end of the fifth link 306 is connected with a second pneumatic mechanism. When the user uses the wave recorder, the wave recorder is placed in the placing cavity 102, and the bottom of the wave recorder is against the first pressure plate 2. , And then drive the first link 203 downward, and then drive the third link 206 through the two second links 205 The upward movement drives the two first pneumatic mechanisms to work, and the two first pneumatic mechanisms of the copper drum drive the two fourth links 304 to move upward. The two fourth links 304 and the fifth links 306 drive the two first links. The two-pressure mechanism fixes the wave recorder. This device has a good effect on the wave recorder and prevents the internal parts of the wave recorder from being damaged during carrying.

Example 2:

Referring to FIGS. 1-5, a carrying frame of a debug wave recorder for a wind generator includes a box body 1, a housing cavity 102 is disposed in the housing body 1, a handle 101 is symmetrically connected to a side wall of the housing body 1, and the cavity is placed. A first pressure plate 2 is connected to the bottom wall of the body 102, and a first link 203 is fixedly connected to the bottom of the first pressure plate 2. The first link 203 is connected with two symmetrical second links 205 and a second link 205 through a pin. The first support base 2051 is rotatably connected to the inner wall of the box body 1. The end of the second link 205 away from the first link 203 is connected to the third link 206 through a pin, and the upper end of the third link 206 is connected to the first air pressure. Mechanism, the output end of the first pneumatic mechanism is connected to a fourth link 304, the upper end of the fourth link 304 is connected to a fifth link 306 through a pin, and the fifth link 306 is connected to the case 1 through the second support base 3061 The inner wall is connected in rotation, and the other end of the fifth link 306 is connected with a second pneumatic mechanism. When the user uses the wave recorder, the wave recorder is placed in the placing cavity 102, and the bottom of the wave recorder is against the first pressure plate 2. , And then drive the first link 203 downward, and then drive the third link 206 through the two second links 205 The upward movement drives the two first pneumatic mechanisms to work, and the two first pneumatic mechanisms of the copper drum drive the two fourth links 304 to move upward. The two fourth links 304 and the fifth links 306 drive the two first links. The two-pressure mechanism fixes the recorder.

The first air pressure mechanism includes a first sealed housing 3, and a first piston 207 is slidably connected to the first sealed housing 3. The first piston 207 is fixedly connected to the third connecting rod 206. The first sealed housing 3 is connected to the fixing seat 102. It is fixedly connected to the inner wall of the box body 1. A second piston 302 is slidably connected to the first sealed housing 3. The upper end of the second piston 302 is fixedly connected to the fourth link 304. The third link 206 moves upward to drive The first piston 207 slides in the first sealed housing 3, and then drives the second piston 302 to slide in the first sealed housing 3, and further drives the fourth link 304 to move upward.

Example 3:

Referring to FIGS. 1-5, a carrying frame of a debug wave recorder for a wind power generator is basically the same as that of Embodiment 2. Furthermore, the fourth link 304 is sleeved with a third spring 305, and the third spring 305 is two The ends abut against the second piston 302 and the inner wall of the first sealed housing 3 respectively. The side wall of the first sealed housing 3 is connected with a vent valve 301. The inner wall of the first sealed housing 3 is symmetrically connected with two stoppers 303. Then, the first sealed housing 3 is deflated by the bleed valve 301, and then the second piston 302 is automatically reset by the third spring 305, and the second piston 302 is restricted by the stopper 303.

Example 4:

Referring to Figs. 1-6, a carrying frame of a debug wave recorder for a wind power generator includes a box body 1, which is provided with a placing cavity 102 therein, and a handle 101 is symmetrically connected to the side wall of the box 1 and the placing cavity A first pressure plate 2 is connected to the bottom wall of the body 102, and a first link 203 is fixedly connected to the bottom of the first pressure plate 2. The first link 203 is connected with two symmetrical second links 205 and a second link 205 through a pin. The first support base 2051 is rotatably connected to the inner wall of the box body 1. The end of the second link 205 away from the first link 203 is connected to the third link 206 through a pin, and the upper end of the third link 206 is connected to the first air pressure. Mechanism, the output end of the first pneumatic mechanism is connected to a fourth link 304, the upper end of the fourth link 304 is connected to a fifth link 306 through a pin, and the fifth link 306 is connected to the case 1 through the second support base 3061 The inner wall is connected in rotation, and the other end of the fifth link 306 is connected with a second pneumatic mechanism. When the user uses the wave recorder, the wave recorder is placed in the placing cavity 102, and the bottom of the wave recorder is against the first pressure plate 2. , And then drive the first link 203 downward, and then drive the third link 206 through the two second links 205 The upward movement drives the two first pneumatic mechanisms to work, and the two first pneumatic mechanisms of the copper drum drive the two fourth links 304 to move upward. The two fourth links 304 and the fifth links 306 drive the two first links. The two-pressure mechanism fixes the recorder.

The first air pressure mechanism includes a first sealed housing 3, and a first piston 207 is slidably connected to the first sealed housing 3. The first piston 207 is fixedly connected to the third connecting rod 206. The first sealed housing 3 is fixed by a fixing seat. 102 与箱体 1。 With the box 1. The inner wall is fixedly connected, and the second piston 302 is slidably connected in the first sealed housing 3. The upper end of the second piston 302 is fixedly connected to the fourth link 304. The first piston 207 is driven by the upward movement of the third link 206 Sliding in the first sealed housing 3 further drives the second piston 302 to slide in the first sealed housing 3, and further drives the fourth link 304 to move upward.

The second pneumatic mechanism includes a sixth link 4, one end of the sixth link 4 is rotatably connected to the fifth link 306 through a pin, and the other end of the sixth link 4 is fixedly connected with a second pressure plate 401, a second pressure plate 401 Two second telescopic rods 402 are symmetrically connected away from the sixth link 4, and the third telescopic plate 404 is connected to an end of the second telescopic rod 402 away from the second pressure plate 401. A fourth spring 403 is sleeved on the second telescopic rod 402. The two ends of the fourth spring 403 abut the second pressure plate 401 and the third pressure plate 404, respectively. The air bag 5 is connected between the second pressure plate 401 and the third pressure plate 404, and the air bag 5 is connected to three second sealed shells 6 through a pressure tube 501. The three second sealed housings 6 are equally spaced on the inner wall of the placing cavity 102. A third piston 601 is slidably connected to the second sealed housing 6, and a push rod 602 and a push rod 602 are fixedly connected to the third piston 601. An arc-shaped pressure plate 604 is connected to the end far from the third piston 601, and the sixth link 4 is moved by the fifth link 306, thereby moving the second pressure plate 401, and the third pressure plate 404 is recorded by the second telescopic rod 402. The wave instrument is compressed, at the same time, the airbag 5 is compressed, and then passes through the compression Tube 501 to drive the third piston seal 601 within the second housing 6 slides so as to drive the platen 604 by arcuate pusher 602 pairs oscillograph fixed.

Example 5:

Referring to FIGS. 1-6, a carrying frame of a debug wave recorder for a wind power generator is basically the same as that in Embodiment 4. A rubber pad 405 is connected to an end of the third pressure plate 404 away from the second pressure plate 401. The friction between the third pressure plate 404 and the wave recorder makes the fixing effect better.

Example 6:

Referring to Figures 1-6, a carrying frame of a debug wave recorder for a wind power generator is basically the same as in Example 4. A fifth spring 603 is sleeved on the push rod 602, and the two ends of the fifth spring 603 are respectively connected to the third piston. The 601 and the inner wall of the second sealed housing 6 abut against each other. After the use is completed, the third piston 601 is automatically reset by the fifth spring 603, thereby facilitating the next installation.

Example 7:

Referring to Figs. 1-3, a carrying frame of a debug wave recorder for a wind power generator is basically the same as in Example 1. A first telescopic rod 201 is symmetrically connected to the bottom of the first pressure plate 2, and the other end of the first telescopic rod 201 is connected with The placing cavity 102 is connected, and a first spring 202 is sleeved on the first telescopic rod 201. The two ends of the first spring 202 abut against the first pressure plate 2 and the placing cavity 102, respectively, through the first telescopic rod 201 and the first spring 202. Played a buffer role.

Example 8:

Referring to Figs. 1-3, a carrying frame of a debugging recorder for a wind power generator is basically the same as that in Embodiment 1. A second link 205 is provided with a through slot 2052, and the first link 203 is connected to the through slot through a pin shaft. 2052 is slidingly connected, so that when the first link 203 moves downward, the second link 205 is driven to move by sliding in the through slot 2052.

Example 9:

Referring to Figs. 1-3, a carrying frame of a debug wave recorder for a wind power generator is basically the same as the first embodiment. A second spring 204 is sleeved on the first link 203, and the two ends of the second spring 204 are respectively connected to the box. The bottom wall of the body 1 and the first pressure plate 2 abut against each other. When the wave recorder is taken out, the second pressure plate 204 can drive the first pressure plate 2 to automatically reset.

The above are only the preferred embodiments of the present utility model, but the scope of protection of the present utility model is not limited to this. Any person skilled in the technical field is within the technical scope disclosed by the present utility model. Equivalent replacements or changes of the new technical solution and the concept of the utility model shall be covered by the protection scope of the utility model.

Claims

A carrying frame for debugging a wave recorder for a wind generator includes a box body (1), characterized in that the box body (1) is provided with a placing cavity (102), and the box body (1) side A grip (101) is symmetrically connected to the wall, a first pressure plate (2) is connected to the bottom wall of the placing cavity (102), and a first link (203) is fixedly connected to the bottom of the first pressure plate (2). The first connecting rod (203) is connected with two symmetrical second connecting rods (205) through a pin, and the second connecting rod (205) rotates with the inner wall of the box body (1) through a first supporting base (2051). Connected, an end of the second link (205) remote from the first link (203) is connected to a third link (206) through a pin, and an upper end of the third link (206) is connected to a first air pressure Mechanism, an output end of the first pneumatic mechanism is connected with a fourth link (304), and an upper end of the fourth link (304) is connected with a fifth link (306) through a pin, and the fifth link The rod (306) is rotatably connected to the inner wall of the box body (1) through a second support base (3061), and the other end of the fifth link (306) is connected with a second air pressure Structure.
The carrying frame of a debug wave recorder for a wind power generator according to claim 1, wherein the first air pressure mechanism comprises a first sealed casing (3), and the first sealed casing (3) A first piston (207) is slidably connected to the first piston (207), the first piston (207) is fixedly connected to the third connecting rod (206), and the first sealed housing (3) is connected to the box body through a fixing seat (102). (1) The inner wall is fixedly connected, a second piston (302) is slidably connected in the first sealed housing (3), and an upper end of the second piston (302) is fixedly connected to a fourth link (304).
The carrying frame of a debug wave recorder for a wind turbine according to claim 2, wherein the fourth link (304) is sleeved with a third spring (305), and the third spring (305 305) The two ends abut against the inner wall of the second piston (302) and the first sealed housing (3), the side wall of the first sealed housing (3) is connected with a relief valve (301), and the first sealed housing Two stops (303) are symmetrically connected to the inner wall of the body (3).
The carrying frame of a debug wave recorder for a wind generator according to claim 2, wherein the second pneumatic mechanism comprises a sixth link (4), and the sixth link (4) One end is rotatably connected to the fifth link (306) through a pin, and the other end of the sixth link (4) is fixedly connected with a second pressure plate (401), and the second pressure plate (401) is far from the sixth link. (4) Two second telescopic rods (402) are symmetrically connected, and the third telescopic rod (404) is connected to an end of the second telescopic rod (402) away from the second press plate (401), and the second telescopic rod A fourth spring (403) is sleeved on (402), and both ends of the fourth spring (403) abut against the second pressure plate (401) and the third pressure plate (404), respectively, and the second pressure plate (401) is in contact with The third pressure plate (404) is connected with an air bag (5), and the air bag (5) is connected with three second sealed housings (6) and three said second sealed housings (6) through a pressure tube (501). Equidistantly distributed on the inner wall of the placing cavity (102), a third piston (601) is slidably connected in the second sealed housing (6), A push rod (602) is fixedly connected to the third piston (601), and an arc-shaped pressure plate (604) is connected to an end of the push rod (602) remote from the third piston (601).
The carrying frame of a debug wave recorder for a wind power generator according to claim 4, wherein a rubber pad (405) is connected to an end of the third pressure plate (404) remote from the second pressure plate (401).
The carrying frame of a debug wave recorder for a wind turbine according to claim 4, wherein a fifth spring (603) is sleeved on the push rod (602), and the fifth spring (603) ) The two ends abut against the inner wall of the third piston (601) and the second sealed housing (6), respectively.
The carrying frame of a debug wave recorder for a wind power generator according to claim 1, characterized in that a first telescopic rod (201) is symmetrically connected to the bottom of the first pressure plate (2), and the first telescopic The other end of the rod (201) is connected to the placing cavity (102). A first spring (202) is sleeved on the first telescopic rod (201), and both ends of the first spring (202) are respectively connected to the first The pressure plate (2) and the placing cavity (102) abut.
The carrying frame of a debug wave recorder for a wind power generator according to claim 1, wherein the second link (205) is provided with a through slot (2052), and the first link (2052) 203) Slidingly connected with the through groove (2052) through the pin shaft.
The carrying frame of a debug wave recorder for a wind power generator according to claim 1, wherein a second spring (204) is sleeved on the first link (203), and the second spring The two ends of (204) abut against the bottom wall of the box (1) and the first pressing plate (2), respectively.

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