CN211310536U - Web hoisting support for wind driven generator blade production - Google Patents

Abstract

The utility model relates to a aerogenerator blade production and manufacture equipment technical field, in particular to aerogenerator blade production is with web support of lifting by crane, lift by crane couple and a plurality of including a plurality of crossbeams, a plurality of and lift by crane the connection interface board, it includes that first crossbeam, second lift by crane the crossbeam to lift by crane the crossbeam, first crossbeam and second lift by crane the crossbeam and be the symmetry setting it lifts by crane the crossbeam to be equipped with the third directly over the first crossbeam to lift by crane the second is equipped with the fourth crossbeam of lifting by crane directly over the crossbeam the left side of first crossbeam that lifts by crane is equipped with fifth stabilizing beam the right side that the second lifted by crane the crossbeam is equipped with sixth stabilizing beam it evenly is equipped with a plurality of first fixed strip bodies to lift by crane between crossbeam and the fifth stabilizing beam. The utility model discloses a wind driven generator blade production is with web support of lifting by crane for transport the web of large-scale wind driven generator blade, its intensity is high, lifts by crane stably.

Description

Web hoisting support for wind driven generator blade production

Technical Field

The utility model relates to a aerogenerator blade production and manufacture equipment technical field, in particular to aerogenerator blade production is with web support of lifting by crane.

Background

The webs, also called internal beams, are mainly used to support the blade shell and bear the bending load to which the blade is subjected, and the webs are often in an i-beam structure to reduce weight. The length of a blade web of a large-scale wind driven generator reaches dozens of meters after the assembly is finished, and the problems of difficulty in transportation, low strength of a transportation frame and the like exist when the assembly of the next step is carried out.

SUMMERY OF THE UTILITY MODEL

The utility model aims at: the utility model provides a wind driven generator blade production is with web support of lifting by crane for transport the web of large-scale wind driven generator blade, its intensity is high, lifts by crane stably.

In order to achieve the above purpose, the technical scheme of the utility model is as follows:

a web plate lifting support for wind driven generator blade production comprises a plurality of lifting cross beams, a plurality of lifting hooks and a plurality of lifting connection interface boards, wherein each lifting cross beam comprises a first lifting cross beam and a second lifting cross beam, the first lifting cross beam and the second lifting cross beam are symmetrically arranged, a third lifting cross beam is arranged right above the first lifting cross beam, a fourth lifting cross beam is arranged right above the second lifting cross beam, a fifth stabilizing cross beam is arranged on the left side of the first lifting cross beam, a sixth stabilizing cross beam is arranged on the right side of the second lifting cross beam, a plurality of first fixing strip bodies are uniformly arranged between the first lifting cross beam and the fifth stabilizing cross beam, and a plurality of second fixing strip bodies are uniformly arranged between the second lifting cross beam and the sixth stabilizing cross beam;

a plurality of first connecting vertical beams are uniformly arranged between the first hoisting cross beam and the third hoisting cross beam, and a plurality of second connecting vertical beams are uniformly arranged between the second hoisting cross beam and the fourth hoisting cross beam;

a plurality of first connecting beams are uniformly arranged between the first hoisting beam and the second hoisting beam, and a plurality of second connecting beams are uniformly arranged between the third hoisting beam and the fourth hoisting beam;

a plurality of first connecting oblique beams and second connecting oblique beams are uniformly distributed between every two first connecting vertical beams, and the first connecting oblique beams and the second connecting oblique beams are alternately distributed;

a plurality of third connecting oblique beams and fourth connecting oblique beams are uniformly distributed between every two second connecting vertical beams, and the third connecting oblique beams and the fourth connecting oblique beams are alternately distributed;

a plurality of fifth connecting oblique beams and sixth connecting oblique beams are uniformly distributed between every two first connecting cross beams, and the fifth connecting oblique beams and the sixth connecting oblique beams are alternately distributed;

a plurality of seventh connecting oblique beams and eighth connecting oblique beams are uniformly distributed between every two second connecting cross beams, and the seventh connecting oblique beams and the eighth connecting oblique beams are alternately distributed;

a plurality of third connecting cross beams, ninth connecting oblique beams and tenth connecting oblique beams are uniformly distributed between each first connecting vertical beam and each second connecting vertical beam, and the ninth connecting oblique beams and the tenth connecting oblique beams are alternately distributed among the third connecting cross beams;

the lifting hook comprises a first lifting hook and a second lifting hook, the first lifting hook and the second lifting hook are respectively limited on the first connecting vertical beam and the second connecting vertical beam through a connecting plate, and the connecting plates are uniformly distributed on the first connecting vertical beam and the second connecting vertical beam;

the lifting connecting interface board is vertically arranged on a supporting plate, lifting through holes are formed in the lifting connecting interface board, and the supporting plate is uniformly distributed above the second lifting cross beam and the fourth lifting cross beam.

The utility model discloses further set up to: the number of the first connecting vertical beams, the number of the second connecting vertical beams, the number of the first connecting cross beams and the number of the second connecting cross beams are equal.

The utility model discloses further set up to: the included angle between the first connection sloping beam and the second connection sloping beam is equal to the included angle between the third connection sloping beam and the fourth connection sloping beam bracket, and the included angle between the fifth connection sloping beam and the sixth connection sloping beam is equal to the included angle between the seventh connection sloping beam and the eighth connection sloping beam.

The utility model discloses further set up to: the fifth connecting oblique beam and the seventh connecting oblique beam are arranged in an intersecting manner, the sixth connecting oblique beam and the eighth connecting oblique beam are arranged in an intersecting manner, and the ninth connecting oblique beam and the tenth connecting oblique beam are arranged in an intersecting manner.

To sum up, the utility model discloses following beneficial effect has:

the hoisting cross beam is uniformly provided with a plurality of hoisting connection interface boards, the first connecting vertical beam and the second connecting vertical beam are uniformly provided with a plurality of hoisting hooks, and the plurality of hoisting connection interface boards and the hoisting hooks are arranged to ensure that the hoisting connection interface boards and the hoisting hooks are not easy to deflect during hoisting, so that the hoisting is more stable;

the first connecting oblique beam to the ninth connecting oblique beam enable the lifting support to be in a plurality of stable triangular structures, so that the strength of the lifting support is improved;

the first connecting vertical beams, the second connecting vertical beams, the first connecting cross beams and the second connecting cross beams are equal in number and are uniformly distributed on the hoisting cross beams, and meanwhile, included angles among the oblique beams are equal and are arranged in a crossed mode, so that the strength of each part in the hoisting support is the same, and the stress is uniform;

the fifth stabilizing cross beam and the sixth stabilizing cross beam are arranged, so that the stress area of the lifting support is increased, and the lifting support is more stable when placed on the ground.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the embodiments or the description of the prior art will be briefly described below.

FIG. 1 is a schematic overall structure diagram of a web plate hoisting bracket for wind turbine blade production;

FIG. 2 is a top view of a web lifting bracket for wind turbine blade production;

FIG. 3 is a partial structural schematic view of a web lifting bracket for wind turbine blade production;

wherein: 1. hoisting the connecting interface board; 2. a support plate; 3. hoisting the cross beam; 31. a first lifting beam; 32. a second lifting beam; 33. a third lifting beam; 34. a fourth lifting beam; 35. a fifth stabilizing beam; 36. a sixth stabilizing beam; 4. a first stationary bar; 5. a second stationary bar; 6. a first connecting vertical beam; 7. a second connecting vertical beam; 8. a first connecting beam 9, a second connecting beam; 10. a first connecting sloping beam; 11. a second connecting oblique beam; 12. a third connecting oblique beam; 13. a fourth connecting oblique beam; 14. a fifth connecting oblique beam; 15. a sixth connecting oblique beam; 16. a seventh connecting oblique beam; 17. eighth connecting oblique beam; 18. a ninth connecting oblique beam; 19. tenth connecting oblique beam; 20. a third connecting beam; 21. hoisting the through hole; 22. lifting the hook; 221. firstly, hanging a hook; 222. a second lifting hook; 23. a connecting plate; 24. a first stabilizing stringer; 25. the second stabilizes the sloping.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, 2 and 3, a web plate lifting support for wind turbine blade production comprises a plurality of lifting beams 3, a plurality of lifting hooks 22 and a plurality of lifting connection interface boards 1, wherein the lifting beams 3 comprise a first lifting beam 31 and a second lifting beam 32, the first lifting beam 31 and the second lifting beam 32 are symmetrically arranged, a third lifting beam 33 is arranged right above the first lifting beam 33, a fourth lifting beam 34 is arranged right above the second lifting beam 32, on the left side of the first lifting beam 313, a fifth stabilizing beam 35 is arranged, on the right side of the second lifting beam 32, a sixth stabilizing beam 36 is arranged, a plurality of first fixed strip bodies 4 are uniformly arranged between the first hoisting beam 31 and the fifth stabilizing beam 35, a plurality of second fixed strip bodies 5 are uniformly arranged between the second hoisting cross beam 32 and the sixth stabilizing cross beam 36;

in this embodiment, the fifth stabilizing beam 35 and the sixth stabilizing beam 36 are arranged to increase the stress area of the hoisting support, so that the hoisting support is more stable when placed on the ground, the first stabilizing oblique beam 24 is arranged above the first fixing strip 4, the second stabilizing oblique beam 25 is arranged above the second fixing strip 5, one end of the first stabilizing oblique beam 24 is limited on the first connecting vertical beam 6, the other end is limited on the fifth stabilizing beam 35, one end of the second stabilizing oblique beam 25 is limited on the second connecting vertical beam 7, and the other end is limited on the sixth stabilizing beam 36.

A plurality of first connecting vertical beams 6 are uniformly arranged between the first hoisting cross beam 31 and the third hoisting cross beam 33, and a plurality of second connecting vertical beams 7 are uniformly arranged between the second hoisting cross beam 32 and the fourth hoisting cross beam 34;

a plurality of first connecting cross beams 8 are uniformly arranged between the first hoisting cross beam 31 and the second hoisting cross beam 32, and a plurality of second connecting cross beams 9 are uniformly arranged between the third hoisting cross beam 33 and the fourth hoisting cross beam 34;

a plurality of first connecting oblique beams 10 and second connecting oblique beams 11 are uniformly distributed between every two first connecting vertical beams 6, and the first connecting oblique beams 10 and the second connecting oblique beams 11 are alternately distributed;

a plurality of third connecting oblique beams 12 and fourth connecting oblique beams 13 are uniformly distributed between every two second connecting vertical beams 7, and the third connecting oblique beams 12 and the fourth connecting oblique beams 13 are alternately distributed;

a plurality of fifth connecting oblique beams 14 and sixth connecting oblique beams 15 are uniformly distributed between each first connecting cross beam 8, and the fifth connecting oblique beams 14 and the sixth connecting oblique beams 15 are alternately distributed;

a plurality of seventh connecting oblique beams 16 and eighth connecting oblique beams 17 are uniformly distributed between every two second connecting cross beams 9, and the seventh connecting oblique beams 16 and the eighth connecting oblique beams 17 are alternately distributed;

a plurality of third connecting cross beams 20, ninth connecting oblique beams 18 and tenth connecting oblique beams 19 are uniformly distributed between each first connecting vertical beam 6 and each second connecting vertical beam 7, and the ninth connecting oblique beams 18 and the tenth connecting oblique beams 19 are alternately distributed among the third connecting cross beams 20;

the lifting hook 22 comprises a first lifting hook 221 and a second lifting hook 222, the first lifting hook 221 and the second lifting hook 222 are respectively limited on the first connecting vertical beam 6 and the second connecting vertical beam 7 through a connecting plate 23, and the connecting plate 23 is uniformly distributed on the first connecting vertical beam 6 and the second connecting vertical beam 7;

the hoisting connection interface board 1 is vertically arranged on a supporting plate 2, the hoisting connection interface board 1 is provided with hoisting through holes 21, and the supporting plates 2 are uniformly distributed above the second hoisting cross beam 32 and the fourth hoisting cross beam 34

In the embodiment, a plurality of hoisting connection interface boards 1 are uniformly arranged on the hoisting cross beam 3, a plurality of hoisting hooks 22 are uniformly arranged on the first connection vertical beam 6 and the second connection vertical beam 7, and the plurality of hoisting connection interface boards 1 and the hoisting hooks 22 are arranged to ensure that the deflection is not easy to occur during hoisting, so that the hoisting is more stable; the arrangement of the first to ninth connecting oblique beams 10 to 18 enables a plurality of stable triangular structures to be present in the lifting support, thereby increasing the strength of the lifting support itself.

The number of the first connecting vertical beams 6, the number of the second connecting vertical beams 7, the number of the first connecting cross beams 8 and the number of the second connecting cross beams 9 are equal; the included angle between the first connecting oblique beam 10 and the second connecting oblique beam 11 is equal to the included angle between the third connecting oblique beam 12 and the fourth connecting oblique beam 13, and the included angle between the fifth connecting oblique beam 14 and the sixth connecting oblique beam 15 is equal to the included angle between the seventh connecting oblique beam 16 and the eighth connecting oblique beam 17; the fifth connecting oblique beam 14 and the seventh connecting oblique beam 16 are arranged to intersect with each other, the sixth connecting oblique beam 15 and the eighth connecting oblique beam 17 are arranged to intersect with each other, and the ninth connecting oblique beam 18 and the tenth connecting oblique beam 19 are arranged to intersect with each other.

The first connecting vertical beams 6, the second connecting vertical beams 7, the first connecting cross beams 8 and the second connecting cross beams 9 are equal in quantity and are uniformly distributed on the hoisting cross beams 3, and meanwhile, included angles among the oblique beams are equal and are arranged in a crossed mode, so that the intensity of each part in the hoisting support is the same, and the stress is uniform.

When the lifting hook is used, the steel wire rope is inserted into the lifting through hole 21 and connected with the lifting rod, and the web plate is fixed on the lifting hook 22 through the connecting rope.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention and not to limit it; although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art will appreciate that; the invention can be modified or equivalent substituted for some technical features; without departing from the spirit of the present invention, it should be understood that the scope of the claims is intended to cover all such modifications and variations.

Claims (4)

1. A web plate lifting support for wind driven generator blade production is characterized by comprising a plurality of lifting cross beams, a plurality of lifting hooks and a plurality of lifting connection interface boards, wherein each lifting cross beam comprises a first lifting cross beam and a second lifting cross beam, the first lifting cross beam and the second lifting cross beam are symmetrically arranged, a third lifting cross beam is arranged right above the first lifting cross beam, a fourth lifting cross beam is arranged right above the second lifting cross beam, a fifth stabilizing cross beam is arranged on the left side of the first lifting cross beam, a sixth stabilizing cross beam is arranged on the right side of the second lifting cross beam, a plurality of first fixing strip bodies are uniformly arranged between the first lifting cross beam and the fifth stabilizing cross beam, and a plurality of second fixing strip bodies are uniformly arranged between the second lifting cross beam and the sixth stabilizing cross beam;

a plurality of first connecting vertical beams are uniformly arranged between the first hoisting cross beam and the third hoisting cross beam, and a plurality of second connecting vertical beams are uniformly arranged between the second hoisting cross beam and the fourth hoisting cross beam;

a plurality of first connecting beams are uniformly arranged between the first hoisting beam and the second hoisting beam, and a plurality of second connecting beams are uniformly arranged between the third hoisting beam and the fourth hoisting beam;

a plurality of first connecting oblique beams and second connecting oblique beams are uniformly distributed between every two first connecting vertical beams, and the first connecting oblique beams and the second connecting oblique beams are alternately distributed;

a plurality of third connecting oblique beams and fourth connecting oblique beams are uniformly distributed between every two second connecting vertical beams, and the third connecting oblique beams and the fourth connecting oblique beams are alternately distributed;

a plurality of fifth connecting oblique beams and sixth connecting oblique beams are uniformly distributed between every two first connecting cross beams, and the fifth connecting oblique beams and the sixth connecting oblique beams are alternately distributed;

a plurality of seventh connecting oblique beams and eighth connecting oblique beams are uniformly distributed between every two second connecting cross beams, and the seventh connecting oblique beams and the eighth connecting oblique beams are alternately distributed;

a plurality of third connecting cross beams, ninth connecting oblique beams and tenth connecting oblique beams are uniformly distributed between each first connecting vertical beam and each second connecting vertical beam, and the ninth connecting oblique beams and the tenth connecting oblique beams are alternately distributed among the third connecting cross beams;

the lifting hook comprises a first lifting hook and a second lifting hook, the first lifting hook and the second lifting hook are respectively limited on the first connecting vertical beam and the second connecting vertical beam through a connecting plate, and the connecting plates are uniformly distributed on the first connecting vertical beam and the second connecting vertical beam;

the lifting connecting interface board is vertically arranged on a supporting plate, lifting through holes are formed in the lifting connecting interface board, and the supporting plate is uniformly distributed above the second lifting cross beam and the fourth lifting cross beam.

2. The wind turbine blade production web lifting support according to claim 1, wherein the first connecting vertical beams, the second connecting vertical beams, the first connecting cross beams and the second connecting cross beams are equal in number.

3. The web lifting support for the production of the wind driven generator blade is characterized in that an included angle between the first connecting oblique beam and the second connecting oblique beam is equal to an included angle between the third connecting oblique beam and the fourth connecting oblique beam support, and an included angle between the fifth connecting oblique beam and the sixth connecting oblique beam is equal to an included angle between the seventh connecting oblique beam and the eighth connecting oblique beam.

4. The wind turbine blade production web lifting bracket according to claim 1, wherein the fifth connecting oblique beam and the seventh connecting oblique beam are arranged to intersect with each other, the sixth connecting oblique beam and the eighth connecting oblique beam are arranged to intersect with each other, and the ninth connecting oblique beam and the tenth connecting oblique beam are arranged to intersect with each other.

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