CN219974686U - Auxiliary mechanism for aligning wind power tower - Google Patents
Auxiliary mechanism for aligning wind power tower Download PDFInfo
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- CN219974686U CN219974686U CN202321621668.9U CN202321621668U CN219974686U CN 219974686 U CN219974686 U CN 219974686U CN 202321621668 U CN202321621668 U CN 202321621668U CN 219974686 U CN219974686 U CN 219974686U
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- 238000013016 damping Methods 0.000 claims abstract description 48
- 235000017166 Bambusa arundinacea Nutrition 0.000 claims description 32
- 235000017491 Bambusa tulda Nutrition 0.000 claims description 32
- 241001330002 Bambuseae Species 0.000 claims description 32
- 235000015334 Phyllostachys viridis Nutrition 0.000 claims description 32
- 239000011425 bamboo Substances 0.000 claims description 32
- 230000005611 electricity Effects 0.000 claims description 32
- 238000009434 installation Methods 0.000 claims description 32
- 230000000694 effects Effects 0.000 abstract description 5
- 210000001503 joint Anatomy 0.000 description 8
- 238000010586 diagram Methods 0.000 description 5
- 230000009286 beneficial effect Effects 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000010248 power generation Methods 0.000 description 1
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Abstract
The utility model discloses an auxiliary mechanism for aligning wind power towers, which belongs to the technical field of wind power towers and comprises a wind power tower A, a wind power tower B, a flange plate, a support frame A and a support frame B, wherein the wind power tower B is arranged below the wind power tower A, the flange plate is fixedly arranged above the inner wall of the wind power tower B and below the inner wall of the wind power tower A, and the opposite flange plates are connected through a plurality of bolts. According to the utility model, after a worker rotates the wind power tower barrels A to drive the mounting frame to slide on the inner side of the mounting groove, so that the plurality of limiting frames A are close to the opposite limiting grooves A, the damping telescopic rod A and the outer spring pop-up limiting frames A slide on the inner side of the limiting grooves A, after the rapid alignment mounting and fixing treatment of one wind power tower barrel A are completed, the worker installs other wind power tower barrels A above the mounted wind power tower barrels A in the same way, and the effect that the worker can perform rapid alignment mounting treatment on the plurality of wind power tower barrels A through the mounting frame is facilitated.
Description
Technical Field
The utility model belongs to the technical field of wind power towers, and particularly relates to an auxiliary mechanism for aligning wind power towers.
Background
The wind power tower is a tower pole for supporting the wind power generator set at high altitude, and the wind power tower is arranged in a hollow shape and is connected and installed from the inside of the wind power tower, so that an auxiliary mechanism for aligning the wind power tower is needed.
According to the search, the application number is CN202223370147.9, and the auxiliary tool for wind power tower connection is provided with two groups of pin-connected positioning pipes, so that the two positioning pipes can be matched with towers with different diameters, the towers are hoisted to the upper part of the tower to be installed through a crane until the positioning pipes are inserted into flange through holes of the tower below to realize butt joint, and the butt joint requirement of a plurality of sections of towers is met; the disadvantages are as follows:
when the auxiliary fixture for wind power tower connection is used by a worker, and a plurality of wind power towers are installed, the positioning pipes are inserted into the through holes of the flange plates, the wedge blocks are extruded and popped up again at the moment and used for limiting the flange of the tower above so as to prevent the positioning pipes from falling off, the tower can be lifted to the position above the tower to be installed through the crane until the positioning pipes are inserted into the through holes of the flange of the tower below, and when the wind power towers are in butt joint installation, the butt joint can be completed due to the fact that the positioning pipes are required to slide into the through holes of the flange between the two wind power towers, and the butt joint treatment can be completed due to the fact that the butt joint surfaces of the positioning pipes are smaller, the worker is required to slightly inconvenience in butt joint of the wind power towers.
Disclosure of Invention
The utility model aims at: in order to solve the problem that the auxiliary tool for connecting the wind power tower is slightly inconvenient to butt joint of the wind power tower, the auxiliary mechanism for aligning the wind power tower is provided.
The technical scheme adopted by the utility model is as follows: the utility model provides an assist mechanism for wind-powered electricity generation tower section of thick bamboo is aimed at, includes wind-powered electricity generation tower section of thick bamboo A, wind-powered electricity generation tower section of thick bamboo B, ring flange, support frame A and support frame B, wind-powered electricity generation tower section of thick bamboo A below is provided with wind-powered electricity generation tower section of thick bamboo B, wind-powered electricity generation tower section of thick bamboo B inner wall top and wind-powered electricity generation tower section of thick bamboo A inner wall top are equal fixed mounting have the ring flange, and pass through a plurality of bolted connection between the relative ring flange, the ring flange inner circle of wind-powered electricity generation tower section of thick bamboo A inner wall top and wind-powered electricity generation tower section of thick bamboo B inner wall top all is provided with support frame A through the bearing rotation, the ring flange inner circle of wind-powered electricity generation tower section of thick bamboo A inner wall below is provided with support frame B through the bearing rotation, be provided with the slip spacing installation mechanism that makes things convenient for the staff to aim at the installation fast between wind-powered electricity generation tower section of thick bamboo A and the support frame B outside.
The utility model provides a wind power tower, including wind power tower, wind power generation installation mechanism, wherein, slip spacing installation mechanism comprises mounting bracket, spout A, spacing A, damping telescopic link A, mounting groove and spacing A, wind power tower A below fixed mounting has the mounting bracket, and the mounting bracket is annular setting, and outer lane below is arc setting in the mounting bracket, wind power tower B top and wind power tower A top embedding are provided with the mounting groove, and the mounting groove is annular setting, and mounting groove top both sides are arc setting, and the mounting bracket agrees with the slip setting at the mounting groove inboard, the mounting bracket below embedding is provided with spout A, spout A has a plurality of, and is the equidistance and encircle setting, the embedding of spout A inside below is provided with spacing A, the embedding of mounting groove inner wall below is provided with spacing A, spacing A has a plurality of, and is the equidistance and encircles setting, and spacing A agrees with the slip setting at spacing A inboard, fixed mounting has damping telescopic link A between spacing A top and the spout A inner wall top, and the damping telescopic link A outside is provided with the spring.
The limiting support mechanism comprises a sliding groove B, damping telescopic rods B, limiting frames B, damping telescopic rods C, limiting blocks, sliding grooves C and limiting grooves B, the sliding grooves B are embedded in the upper portion of the supporting frame A, the sliding grooves B are four and are equidistantly arranged in a surrounding mode, the damping telescopic rods B are fixedly installed below the inner walls of the sliding grooves B, springs are arranged outside the damping telescopic rods B in a matching mode, the limiting frames B are fixedly installed above the end portions of the damping telescopic rods B, the sliding grooves C are embedded in the lower portion of the supporting frame B, the four sliding grooves C are arranged in an equidistantly surrounding mode and are arranged inside the sliding grooves C in a matching mode, the limiting grooves B are embedded in the side portions of the inner walls of the sliding grooves C, the damping telescopic rods C are fixedly installed on the sides of the side portions of the limiting frames B, the limiting blocks are fixedly installed on the sides of the end portions of the damping telescopic rods C in a matching mode, and the limiting blocks are arranged on the inner sides of the limiting grooves B in a matching mode.
In summary, due to the adoption of the technical scheme, the beneficial effects of the utility model are as follows:
1. this kind of an auxiliary mechanism for wind-powered electricity generation tower section of thick bamboo aligns is through being provided with sliding spacing installation mechanism, can make the staff pass through between mounting bracket, spout A, spacing A, damping telescopic link A, mounting groove and the spacing A cooperation, utilize between cambered surface of outer lane in the mounting bracket below and the cambered surface of mounting groove top both sides, make the mounting bracket will be through cambered surface automatic alignment and slide into the mounting groove inboard, make things convenient for the staff to carry out the effect of quick alignment installation through the mounting bracket to a plurality of wind-powered electricity generation tower section of thick bamboo A.
2. This kind of an auxiliary mechanism for wind-powered electricity generation tower section of thick bamboo aligns is through being provided with spacing supporting mechanism, can make the staff pass through spout B, damping telescopic link B, spacing B, damping telescopic link C, the stopper, cooperation between spout C and the spacing groove B, utilize spacing B to push spout C through damping telescopic link B, after the stopper pushes spacing groove B through damping telescopic link C, can carry out supplementary spacing support processing between support frame A and the support frame B, make things convenient for the staff to carry out supplementary support to wind-powered electricity generation tower section of thick bamboo A after, can avoid wind-powered electricity generation tower section of thick bamboo A to produce the effect of removing when fixed.
Drawings
FIG. 1 is a schematic diagram of a front perspective structure of a wind power tower of the present utility model;
FIG. 2 is a schematic diagram of a front cross-sectional structure of a wind power tower in the utility model;
FIG. 3 is a schematic diagram of the enlarged construction of FIG. 2 at A in accordance with the present utility model;
FIG. 4 is a schematic diagram of the enlarged structure of FIG. 2B in accordance with the present utility model;
fig. 5 is a schematic diagram showing the second enlarged structure of the embodiment a in fig. 2 according to the present utility model.
The marks in the figure: 1. wind power tower A; 101. a mounting frame; 102. a chute A; 103. a limiting frame A; 104. damping telescopic rod A; 2. a wind power tower barrel B; 201. a mounting groove; 202. a limit groove A; 3. a flange plate; 4. a supporting frame A; 401. a chute B; 402. damping telescopic rod B; 403. a limiting frame B; 404. damping telescopic rod C; 405. a limiting block; 5. a support B; 501. a chute C; 502. and a limit groove B.
Detailed Description
The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.
In the utility model, the following components are added:
embodiment one: referring to fig. 1-5, an auxiliary mechanism for aligning wind power tower cylinders comprises a wind power tower cylinder A1, a wind power tower cylinder B2, a flange plate 3, a support frame A4 and a support frame B5, wherein the wind power tower cylinder B2 is arranged below the wind power tower cylinder A1, the flange plate 3 is fixedly installed above the inner wall of the wind power tower cylinder B2 and above and below the inner wall of the wind power tower cylinder A1, the opposite flange plates 3 are connected through a plurality of bolts, the support frame A4 is arranged on the inner ring of the flange plate 3 above the inner wall of the wind power tower cylinder A1 and above the inner wall of the wind power tower cylinder B2 through bearing rotation, the support frame B5 is arranged on the inner ring of the flange plate 3 below the inner wall of the wind power tower cylinder A1 through bearing rotation, a sliding limit installation mechanism which is convenient for workers to rapidly align to install is arranged between the wind power tower cylinder A1 and the outer side of the support frame B5, and a limit support mechanism which can carry out auxiliary support treatment between the connected wind power tower cylinders is arranged between the support frame A4 and the outer side of the support frame B5.
2-3, further, the sliding limit mounting mechanism is composed of a mounting frame 101, a sliding chute A102, a limit frame A103, a damping telescopic rod A104, a mounting groove 201 and a limit groove A202;
the installation frame 101 is fixedly installed below the wind power tower A1, the installation frame 101 is in an annular shape, the lower parts of the inner ring and the outer ring of the installation frame 101 are in arc-shaped arrangement, the installation groove 201 is embedded above the wind power tower B2 and above the wind power tower A1, the installation groove 201 is in annular shape, the two sides above the installation groove 201 are in arc-shaped arrangement, the installation frame 101 is matched with the sliding arrangement inside the installation groove 201, the sliding groove A102 is embedded below the installation frame 101, a plurality of sliding grooves A102 are arranged in an equidistant surrounding arrangement, the limiting frame A103 is arranged below the inner wall of the installation groove 201 in a sliding manner, the limiting groove A202 is arranged in a plurality of equidistant surrounding arrangement, the limiting frame A103 is matched with the sliding arrangement inside the limiting groove A202, the damping telescopic rod A104 is fixedly installed between the upper side of the limiting frame A103 and the upper side of the inner wall of the sliding groove A102, when a worker needs to install the wind power tower, springs are arranged on the outer side of the damping telescopic rod A104 in a matching manner, after the worker carries a plurality of wind power tower cylinders A1 and wind power tower cylinders B2 to an installation site, after fixing the wind power tower cylinders B2 with matched wind power tower bases, after one wind power tower cylinder A1 is arranged above the wind power tower cylinders B2 through a crane, when the cambered surface of a mounting frame 101 below the wind power tower cylinder A1 contacts the cambered surface above the installation groove 201, the mounting frame 101 automatically aligns and slides into the inner side of the installation groove 201 through the cambered surface, at the moment, the worker rotates the wind power tower cylinder A1 to drive the mounting frame 101 to slide in the inner side of the installation groove 201, after a plurality of limiting frames A103 are close to opposite limiting grooves A202, the damping telescopic rod A104 and the outer side springs are popped up to slide into the inner side of the limiting frames A202, and after rapid alignment installation and fixing treatment of one wind power tower cylinder A1 are completed, the staff installs other wind-powered electricity generation tower section of thick bamboo A1 in the wind-powered electricity generation tower section of thick bamboo A1 top that finishes with the same mode again, and the effect of quick alignment installation processing can be carried out to a plurality of wind-powered electricity generation tower section of thick bamboo A1 through mounting bracket 101 to the convenience staff.
Referring to fig. 2-4, further, the limit supporting mechanism is composed of a chute B401, a damping telescopic rod B402, a limit frame B403, a damping telescopic rod C404, a limit block 405, a chute C501 and a limit groove B502;
the upper part of the supporting frame A4 is embedded with four sliding grooves B401, the sliding grooves B401 are equidistantly and circumferentially arranged, the damping telescopic rod B402 is fixedly arranged below the inner wall of the sliding groove B401, the side of the end part of the damping telescopic rod B402 is provided with a spring in a matched manner, the upper part of the end part of the damping telescopic rod B402 is fixedly provided with a limiting frame B403, the lower part of the supporting frame B5 is embedded with a sliding groove C501, the sliding grooves C501 are four and equidistantly and circumferentially arranged, the limiting frame B403 is matched and slidingly arranged at the inner side of the sliding groove C501, the side of the inner wall of the sliding groove C501 is embedded with a limiting groove B502, the side of the limiting frame B403 is fixedly provided with a damping telescopic rod C404, the outer side of the damping telescopic rod C404 is provided with a spring in a matched manner, the side of the end part of the damping telescopic rod C404 is fixedly provided with a limiting block 405, the limiting block 405 is matched and slidingly arranged at the inner side of the limiting groove B502, after a worker aligns and installs the tower A1 and the wind tower B2, after a worker in the wind power tower A1 moves to the joint between the wind power tower A1 and the wind power tower B2 through a ladder, the support frame A4 or the support frame B5 is pushed to rotate through a bearing, after the limit frame B403 is close to the chute C501, the damping telescopic rod B402 and the outer spring pop-up limit frame B403 slide into the inner side of the opposite chute C501, the damping telescopic rod C404 and the outer spring pop-up limit block 405 slide into the inner side of the limit groove B502, after limiting support treatment is carried out between the support frame A4 and the support frame B5, auxiliary support treatment is finished between the wind power tower A1 and the wind power tower B2, after the worker fixes the opposite flange 3 through a plurality of bolts, installation and fixation of one wind power tower A1 are finished, and after the wind power tower A1 is supported in an auxiliary mode, the effect that the wind power tower A1 moves during fixing can be avoided can be conveniently carried out by the worker.
Embodiment two:
as shown in fig. 5, according to the utility model, a mounting frame 101 is fixedly installed below a wind power tower A1, the mounting frame 101 is annularly arranged, the lower part of the inner ring and the outer ring of the mounting frame 101 is arc-shaped, a mounting groove 201 is embedded and arranged above a wind power tower B2 and above a wind power tower A1, the mounting groove 201 is annularly arranged, two sides above the mounting groove 201 are arc-shaped, the mounting frame 101 is matched with the embodiment of sliding arrangement inside the mounting groove 201, another embodiment exists, the mounting frame 101 is fixedly installed below the wind power tower A1, the mounting frame 101 is annularly arranged, the outer ring of the mounting frame 101 is obliquely arranged, the upper part of the wind power tower B2 and the upper part of the wind power tower A1 are embedded and provided with the mounting groove 201, the mounting groove 201 is annularly arranged, the outer ring of the inner wall of the mounting groove 201 is obliquely arranged, and the mounting frame 101 is matched with the sliding arrangement inside the mounting groove 201, when a worker places one wind power tower A1 above the wind power tower B2, the inclined surface of the mounting frame 101 contacts the inclined surface of the mounting frame 101 above the mounting groove 201, and the inclined surface of the wind power tower A1 is aligned with the inclined surface of the mounting groove 201, and the crane is more conveniently aligned with the first inclined surface of the mounting frame.
Working principle: firstly, when a worker needs to install wind power towers, carrying a plurality of wind power towers A1 and wind power towers B2 to an installation site, after the worker fixes the wind power towers B2 with matched wind power tower bases, placing one wind power tower A1 above the wind power towers B2 through a crane, when the cambered surface of a mounting frame 101 below the wind power towers A1 contacts the cambered surface above an installation groove 201, automatically aligning and sliding the mounting frame 101 into the inner side of the installation groove 201 through the cambered surface, at the moment, the worker rotates the wind power towers A1 to drive the mounting frame 101 to slide in the inner side of the installation groove 201, so that a plurality of limiting frames A103 are close to opposite limiting grooves A202, a damping telescopic rod A104 and an outer spring pop out of the limiting frames A103 to slide into the inner side of the limiting grooves A202, completing quick alignment installation and fixing treatment of one wind power tower A1, then, after a worker in the wind power tower A1 moves to the joint between the wind power tower A1 and the wind power tower B2 through a ladder, the support frame A4 or the support frame B5 is pushed to rotate through a bearing, after the limit frame B403 is close to the chute C501, the damping telescopic rod B402 and the outside spring pop-up limit frame B403 slide into the inner side of the opposite chute C501, the damping telescopic rod C404 and the outside spring pop-up limit block 405 slide into the inner side of the limit groove B502, after limiting support treatment is carried out between the support frame A4 and the support frame B5, auxiliary support treatment is finished between the wind power tower A1 and the wind power tower B2, after the worker fixes the opposite flange 3 through a plurality of bolts, the installation and fixation of one wind power tower A1 are finished, and finally, the worker installs other wind power towers A1 above the installed wind power tower A1 in the same manner and carries out fixing treatment.
The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.
Claims (6)
1. The utility model provides an assist mechanism for wind-powered electricity generation tower section of thick bamboo is aimed at, includes wind-powered electricity generation tower section of thick bamboo A (1), wind-powered electricity generation tower section of thick bamboo B (2), ring flange (3), support frame A (4) and support frame B (5), wind-powered electricity generation tower section of thick bamboo A (1) below is provided with wind-powered electricity generation tower section of thick bamboo B (2), wind-powered electricity generation tower section of thick bamboo B (2) inner wall top and wind-powered electricity generation tower section of thick bamboo A (1) inner wall top equal fixed mounting have ring flange (3), and pass through a plurality of bolted connection between relative ring flange (3), wind-powered electricity generation tower section of thick bamboo A (1) inner wall top and ring flange (3) inner circle of wind-powered electricity generation tower section of thick bamboo B (2) inner wall top all are provided with support frame A (4) through bearing rotation, ring flange (3) inner circle of wind-powered electricity generation tower section of thick bamboo A (1) inner wall below is provided with support frame B (5), its characterized in that: a sliding limit installation mechanism which is convenient for workers to rapidly align and install is arranged between the outer sides of the wind power tower A (1) and the wind power tower B (2), and a limit support mechanism which can assist in supporting between the connected wind power towers is arranged between the outer sides of the support frame A (4) and the support frame B (5).
2. An auxiliary mechanism for wind power tower alignment as defined in claim 1, wherein: the sliding limit mounting mechanism consists of a mounting frame (101), a sliding chute A (102), a limit frame A (103), a damping telescopic rod A (104), a mounting groove (201) and a limit groove A (202);
wind-powered electricity generation tower section of thick bamboo A (1) below fixed mounting has mounting bracket (101), wind-powered electricity generation tower section of thick bamboo B (2) top and wind-powered electricity generation tower section of thick bamboo A (1) top embedding are provided with mounting groove (201), and mounting bracket (101) fit sliding setting is inboard at mounting groove (201), mounting bracket (101) below embedding is provided with spout A (102), spout A (102) have a plurality of, and are the equidistance and encircle setting, the inside below slip of spout A (102) is provided with spacing A (103), mounting groove (201) inner wall below embedding is provided with spacing groove A (202), and spacing A (103) fit sliding setting is inboard at spacing groove A (202), fixed mounting has damping telescopic link A (104) between spacing A (103) top and spout A (102) inner wall top, and damping telescopic link A (104) outside is provided with the spring in a matched manner.
3. An auxiliary mechanism for wind power tower alignment as defined in claim 1, wherein: the limiting and supporting mechanism consists of a sliding chute B (401), a damping telescopic rod B (402), a limiting frame B (403), a damping telescopic rod C (404), a limiting block (405), a sliding chute C (501) and a limiting groove B (502);
the novel damping telescopic rod is characterized in that a sliding groove B (401) is embedded in the upper portion of the supporting frame A (4), a damping telescopic rod B (402) is fixedly arranged below the inner wall of the sliding groove B (401), a spring is arranged on the outer side of the damping telescopic rod B (402), a limiting block (405) is fixedly arranged above the end portion of the damping telescopic rod B (402), a sliding groove C (501) is embedded in the lower portion of the supporting frame B (5), the limiting block B (403) is arranged on the inner side of the sliding groove C (501) in a sliding fit manner, a limiting groove B (502) is embedded in the side of the inner wall of the sliding groove C (501), a damping telescopic rod C (404) is fixedly arranged on the side of the limiting frame B (403), a spring is arranged on the outer side of the damping telescopic rod C (404), a limiting block (405) is fixedly arranged on the side of the end portion of the damping telescopic rod C (404), and the limiting block (405) is arranged on the inner side of the limiting groove B (502) in a sliding fit manner.
4. An auxiliary mechanism for wind power tower alignment as claimed in claim 2, wherein: the mounting frame (101) is in an annular shape, the lower part of the inner ring and the outer ring of the mounting frame (101) is in an arc shape, the mounting groove (201) is in an annular shape, and two sides above the mounting groove (201) are in arc shapes.
5. An auxiliary mechanism for wind power tower alignment as claimed in claim 2, wherein: the limiting grooves A (202) are arranged in a plurality of mode and are equidistantly and circumferentially arranged.
6. An auxiliary mechanism for wind power tower alignment according to claim 3, wherein: four sliding grooves B (401) are formed in an equidistant encircling mode, and four sliding grooves C (501) are formed in an equidistant encircling mode.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202321621668.9U CN219974686U (en) | 2023-06-26 | 2023-06-26 | Auxiliary mechanism for aligning wind power tower |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202321621668.9U CN219974686U (en) | 2023-06-26 | 2023-06-26 | Auxiliary mechanism for aligning wind power tower |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN219974686U true CN219974686U (en) | 2023-11-07 |
Family
ID=88584505
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202321621668.9U Active CN219974686U (en) | 2023-06-26 | 2023-06-26 | Auxiliary mechanism for aligning wind power tower |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN219974686U (en) |
-
2023
- 2023-06-26 CN CN202321621668.9U patent/CN219974686U/en active Active
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