CN219994068U - Wind-proof vibration hoop and container crane - Google Patents

Abstract

The utility model provides a wind-proof vibration hoop and a container crane, which are used for large wharf equipment, in particular to a wind-proof vibration structure of a wharf equipment supporting circular tube, comprising the following components: the anchor clamps are sleeved on a supporting pipe of the equipment and are uniformly distributed along the length direction of the supporting pipe; the mounting plates are uniformly distributed in the circumferential direction of the anchor ear; the plurality of guide battens, both ends are connected between two adjacent staple bolts through the mounting panel, and every guide batten all inclines to set up relative the axis of stay tube, and incline direction is unanimous and the inclination is the same. According to the wind vibration prevention hoop, the spiral battens of the space special-shaped structures are converted into the guide battens to be spliced, so that the manufacturing and mounting difficulty of each part is reduced, the manufacturing and mounting efficiency is improved, the problem that the wind vibration prevention effect is poor due to poor batten mounting forming degree is solved, and a good wind vibration prevention effect is achieved. The container crane provided by the utility model is provided with the windproof vibration hoop, and has good windproof vibration effect and long service life.

Description

Wind-proof vibration hoop and container crane

Technical Field

The utility model relates to the technical field of wharf equipment, in particular to a wind-proof vibration hoop and a container crane.

Background

At present, large round pipes are often used as supports for large wharf equipment and the like, and wind vibration is easily generated by the support pipes in windy occasions, so that wind vibration prevention design is needed for the support pipes.

At present, the method for preventing wind vibration on the support tube mainly comprises the step of arranging a spiral wind vibration preventing hoop structure on the support tube to achieve the purpose of preventing wind vibration.

The spiral wind vibration prevention hoop is an optimal supporting tube wind vibration prevention structure, and the spiral guide batten arranged on the round tube can effectively guide wind vertically acting on the supporting tube to rotate around the supporting tube, effectively solve the vertical wind force on the supporting tube and solve the wind prevention problem.

Because the spiral hoop is of a space special-shaped structure, the spiral hoop is very difficult to manufacture and install, and the corresponding hoops and the corresponding battens can be assembled and welded section by section only according to the approximately required direction on site, the regular forming degree of the installation of the guide battens is poor, and the wind guiding effect is greatly reduced. In addition, the spiral vibration hoop has high manufacturing cost due to the characteristics.

Disclosure of Invention

In view of the above, the present utility model provides a wind vibration preventing hoop, which has a structure capable of reducing manufacturing and installation difficulties and manufacturing costs of the wind vibration preventing hoop, improving manufacturing and installation efficiency, and improving post-installation formability.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

a wind-resistant vibration band comprising:

the anchor clamps are sleeved on a supporting tube of the equipment and are uniformly distributed along the length direction of the supporting tube;

the mounting plates are uniformly distributed in the circumferential direction of the anchor ear;

the guide battens are obliquely arranged relative to the axis of the stay tube, and the oblique directions are consistent and the oblique angles are the same.

Optionally, the mounting plate is arranged along the radial direction of the anchor ear, and the mounting plate is rotationally connected with the anchor ear.

Optionally, the mounting plate includes two mounting lugs, one of which can be connected to one of the guide strips on one side of the anchor ear, and the other of which can be connected to one of the guide strips on the other side of the anchor ear.

Optionally, the two mounting lugs of the mounting plate are symmetrically arranged relative to the rotation axis of the mounting plate.

Optionally, the two mounting ears of the mounting plate are disposed on the same plane of the mounting plate.

Optionally, the mounting panel includes flaky mounting panel body and round pin axle sleeve, the round pin axle sleeve sets up on the one side of mounting panel body, the mounting panel body is in the part of round pin axle sleeve axis both sides forms respectively two the mounting ear, the mounting panel pass through the round pin axle with the staple bolt rotates to be connected.

Optionally, the support tube is further provided with a positioning ear plate for fixing the anchor ear, and the positioning ear plate is uniformly distributed along the circumferential direction of the support tube.

Optionally, the anchor ear includes at least two arc stirrups, all arc stirrups encircle along the pipe support circumference and form the anchor ear.

Optionally, the staple bolt includes two at least arc stirrups, every two are adjacent set up one between the locating otic placode the arc stirrups, the arc stirrups pass through the extension board at its both ends respectively with two the locating otic placode is connected, all the arc stirrups are followed the pipe support circumference is encircleed and is formed the staple bolt.

The windproof hoop provided by the utility model has a simple integral structure, and realizes the installation and positioning of a plurality of guide strips by converting the spiral strips of the existing space special-shaped structure into the anchor clamps and the installation plates, so that the manufacturing and installation difficulties and the manufacturing cost of each part are reduced, the manufacturing and installation efficiency is improved, the problems of poor forming degree and poor windproof vibration effect after the installation of the existing strips are solved, and a good windproof vibration prevention effect is achieved.

The utility model also provides a container crane, which comprises the windproof vibration hoop, wherein the windproof vibration hoop is arranged on a supporting pipe of the container crane.

The wind-proof vibration hoop is arranged on the supporting pipe of the container crane, so that the wind-proof vibration effect of strong wind at a wharf on the container crane can be effectively reduced, the structural damage of the wind vibration on the container crane is reduced, and the service life of the container crane is prolonged.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present utility model, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of the wind-vibration resistant cuff of the present utility model mounted on a device stay tube;

FIG. 2 is a schematic view of a cross section of a support tube with a wind-resistant vibration hoop installed;

FIG. 3 is a schematic view of a semi-circular arc-shaped strap and mounting plate mounted thereon.

FIG. 4 is a schematic view of the other view of FIG. 3;

FIG. 5 is a schematic view of a mounting plate;

FIG. 6 is a schematic view of a single guide slat;

FIG. 7 is a schematic distribution diagram of a locating ear plate on a device stay tube;

fig. 8 is a schematic diagram of a manufacturing and installation flow of the wind vibration prevention hoop according to the scheme.

In fig. 1-7:

1. supporting the pipe; 102. positioning the ear plate;

210. a hoop; 211. a semicircular arc-shaped hooping strip; 212. a mounting plate; 213. a pin shaft; 220. and a guide slat.

Detailed Description

The utility model provides a wind-proof vibration hoop, which has the structure that the manufacturing difficulty, the mounting difficulty and the manufacturing cost of the wind-proof vibration hoop can be reduced, the manufacturing and mounting efficiency can be improved, and the molding degree after mounting can be improved. The utility model also provides a container crane provided with the wind-proof vibration hoop, which has good wind-proof vibration effect and long service life.

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.

As shown in fig. 1-7, the embodiment of the utility model provides a wind-proof hoop, which comprises a plurality of hoops 210, a plurality of mounting plates 212 and a plurality of guide strips 220, wherein the annular hoops 210 are sleeved on a supporting pipe 1 of large dock equipment, a plurality of hoops 210 are arranged on one supporting pipe 1, and the hoops 210 are uniformly distributed along the length direction of the supporting pipe 1 and provide a foundation for the mounting and positioning of the guide strips 220 in the next step; the mounting plates 212 are uniformly distributed around the hoops 210, and two ends of one guide slat 220 are connected and positioned between two hoops 210 through two mounting plates 212 on adjacent hoops 210, so that a plurality of guide slats 220 can be installed between each pair of adjacent hoops 210.

Each guide slat 220 is obliquely arranged relative to the axis of the stay tube 1, and the oblique directions are consistent and the oblique angles are the same; namely, each guide slat 220 has an included angle with the axis of the supporting tube 1 and the included angles have the same degree, so that a scheme of forming a spiral line by connecting the guide slats 220 end to end in the length direction of the supporting tube 1 can be selected, or a scheme of not forming a spiral line can be selected, namely, the guide slats 220 are not connected end to end in the length direction of the supporting tube 1 and are staggered in order, so that an array which is formed by a plurality of inclined guide slats 220 and is staggered to turbulence wind can be formed. Of course, forming the helix is a more efficient solution, which saves more mounting plates 212, and is more convenient to install.

The wind-vibration-preventing hoop has a simple integral structure, the sizes of the hoops 210 and the mounting plates 212 can be set to be consistent when in design, the sizes of the guide battens 220 are also set to be consistent, and the mould or the template with the same size can be used for realizing mass standardized production and manufacturing, so that the manufacturing cost of each part is reduced, and the manufacturing efficiency is improved;

the installation difficulty is remarkably reduced and the installation efficiency is improved by converting the spiral batten with the existing space special-shaped structure into a plurality of relatively short guide battens 220 for splicing due to the segmented installation when installing the guide batten 220;

in addition, since the guide strips 220 installed in sections are consistent in size, if a scheme of forming a spiral line is selected, the spiral line after installation is good in forming degree, the wind vibration prevention effect is improved, and a good wind vibration prevention effect is achieved.

For standardization and installation convenience of the anchor ear 210, the number of the mounting plates 212 on each anchor ear 210 is the same and the number is even, such as 2,4, etc.; considering that one hoop 210 corresponds to two mounting plates 212, that is, two guide strips 220 are connected to form one circle around the supporting tube 1, the division degree is insufficient, and the processing and the mounting are still not very convenient, so in this embodiment, as shown in fig. 1 and 2,4 mounting plates 212 are provided on each hoop 210.

In order to form the guide strips 220 into a spiral line end to end in the length direction of the stay tube, there are at least two implementations, one: when the hoops 210 are installed, the installation plates 212 on two adjacent hoops 210 are in one-to-one correspondence, namely, the connecting line of each pair of installation plates 212 is parallel to the axis of the supporting tube 1, and N installation plates 212 are arranged on one hoop 210, then in the length direction of the supporting tube 1, the connecting line of each installation plate 212 is N straight lines parallel to the axis of the supporting tube 1, when the guide lath 220 is installed, the upper end of the guide lath 220 is connected with one installation plate 212 of the hoops 210 above the guide lath 220, the lower end of the guide lath 220 is connected with the installation plate 212 on the left side or the right side of the corresponding installation plate 212 of the lower hoop 210 to realize the inclination of angles, and if one guide lath 220 is inclined rightwards, all the guide laths 220 are inclined leftwards so as to realize the spiral line formation and the consistency of the directions of the guide lath 220; mode two: the inclination of the guide lath 220 can be realized by staggering the corresponding mounting plates 212 on the adjacent anchor ears 210 by an angle when the anchor ears 210 are mounted, namely, the mounting plates 212 of the anchor ears 210 form a spiral line along the length direction of the supporting tube 1, and when the guide lath 220 is mounted, the guide lath 220 is mounted between the two mounting plates 212 which are closest to the adjacent anchor ears 210; thus, the guide strips 220 can form a spiral line in a pair by pair in the length direction of the supporting tube 1, and thus, the N mounting plates 212 are arranged on one hoop 210, so that N spiral lines can be formed on the supporting tube 1.

As shown in fig. 1, in the wind-proof hoop, the connecting line between two mounting plates 212 closest to two adjacent hoops 210 is parallel to the axis of the supporting tube 1, that is, a method of installing the hoops 210 in a first mode is adopted, that is, when installing the hoops 210, each mounting plate 212 on two adjacent hoops 210 corresponds to each other one by one, that is, the connecting line of each pair of mounting plates 212 is parallel to the axis of the supporting tube 1, and N mounting plates 212 are arranged on one hoop 210, so that in the length direction of the supporting tube 1, the connecting line of each mounting plate 212 is N straight lines parallel to the axis of the supporting tube 1. Because the connecting lines of the corresponding mounting plates 212 on the hoops 210 are straight lines, the installation and positioning of the hoops 210 are convenient, and the detection and calibration of whether the positions of the hoops 210 are installed in place are also convenient.

Further, as shown in fig. 2-5, mounting plate 212 is disposed radially of anchor ear 210, i.e., mounting plate 212 is perpendicular to a tangential plane at the junction with anchor ear 210; and mounting plate 212 is rotatably coupled to anchor ear 210.

The mounting plate 212 is free to rotate and is perpendicular to the tangent plane at the junction with the anchor ear 210 regardless of rotation, and the mounting plate 212 thus provided can automatically accommodate the angle required for mounting the guide strip 220.

Further, as shown in fig. 4 and 5, the mounting plate 212 includes two mounting ears, one of which can be connected to one guide strip 220 on one side of the anchor ear 210 and the other of which can be connected to one guide strip 220 on the other side of the anchor ear 210. In this way, the two mounting ears of each mounting plate 212 can be respectively connected with one guide slat 220, that is, one mounting plate 212 on the anchor ear 210 can be respectively connected with two guide slats 220 on two sides of the anchor ear 210, which not only saves the number of mounting plates 212, but also can facilitate the end-to-end connection of the guide slats.

Further, as shown in fig. 4 and 5, the two mounting ears of the mounting plate 212 are symmetrically disposed with respect to the rotational axis of the mounting plate 212. The two symmetrically disposed mounting ears are mirror images in configuration so that the mounting plate 212 is fixedly coupled to the ends of the two guide strips 220, respectively.

Further, as shown in fig. 4 and 5, the two mounting lugs of the mounting plate 212 are disposed on the same plane of the mounting plate 212, and when the mounting lugs are connected with the end portions of the guide strips 220, the end portions of the guide strips 220 are attached to the plane of the mounting lugs for mounting and fixing, so that the end portions of the guide strips 220 respectively connected with the two mounting lugs are also on the same plane or parallel to each other, and the connection smoothness of the two guide strips 220 connected end to end through the mounting plate 212 is ensured. This can be achieved in at least two ways, one is to use a one-piece mounting plate body and a rotating shaft provided with one side of the mounting plate body, and the other is to connect one mounting lug on both sides of the rotating shaft of the mounting plate respectively, the former is relatively simple in manufacturing process, and the latter is relatively complex.

Further, as shown in fig. 4 and 5, the mounting plate 212 includes a sheet-shaped mounting body, a pin shaft sleeve is fixedly arranged in the middle of one side of the mounting body, and the pin shaft sleeve can be fixedly connected to the middle of one side of the sheet-shaped mounting body in a welding manner. The lower end of the pin shaft sleeve is level with the lower edge of the installation body, a gap is formed between the upper end of the pin shaft sleeve and the upper edge of the installation body, and a gap is formed at the gap part, so that the pin shaft 213 is conveniently installed.

The parts of the installation body, which are positioned at the two sides of the axis of the pin shaft sleeve, respectively form two installation lugs which are symmetrical relative to the axis of the pin shaft sleeve, and each installation lug can be respectively connected with one guide slat 220, so that one installation plate 212 on the anchor ear 210 can be respectively connected with the two guide slats 220 at the two sides of the anchor ear 210, thereby saving the number of the installation plates 212 and facilitating the installation.

After the mounting lugs on one side of the mounting plate 212 on the hoop 210 are fixedly connected with the guide battens 220 on the side, the mounting plate 212 is in a semi-positioning state; when the mounting lugs on both sides of one mounting plate 212 are connected with the guide strips 220 on both sides of the anchor ear 210, the angle of the mounting plate 212 can be automatically fixed. When the anchor ear 210 is installed on the support pipe 1, and then the guide lath 220 is installed from one end to the other end along the length direction of the support pipe 1, one end of the guide lath 220 is connected with one installation ear of the installation plate 212 in a semi-positioning state on one side anchor ear 210, and then connected with one installation ear of the installation plate 212 in a completely free rotation state on the other side anchor ear 210, so that the installation difficulty is low.

In addition, after the two guide battens 220 on two sides of the anchor ear 210 are connected through the same rotatable mounting plate 212 on the anchor ear 210, the final angle of the mounting plate 212 can be well along the required spiral direction because the stress is the same after the two sides are tightly assembled, so that the two guide battens 220 connected with the two mounting lugs can realize regular smooth transition, thereby greatly improving the diversion effect of the spiral wind-proof hoop on wind power and improving the wind-proof effect of the spiral wind-proof hoop.

As shown in fig. 6, the guide strip 220 is an arc-shaped sheet strip, and the upper end of the guide strip 220 is connected to one mounting ear of one mounting plate 212 of the upper hoop 210, and the lower end is connected to one mounting ear of the mounting plate 212 of the lower hoop 210 corresponding to the left or right side of the mounting plate 212. All the guide battens 220 on the stay tube 1 have the same size, and can realize mass standardized production and manufacture by using the molds or templates with the same size, thereby reducing the manufacturing cost of each part and improving the manufacturing efficiency; the guide rail 220 is provided obliquely to the outer periphery of the stay 1, and is formed into an arcuate sheet-like rail so as to conform to the shape of the outer periphery of the stay 1.

Further, as shown in fig. 7, in the above wind-proof hoop, in order to enable the hoop 210 to be firmly mounted on the supporting tube 1, the supporting tube 1 is further provided with positioning ear plates 102 for fixing the hoop 210, and in order to facilitate the mounting of the hoop 210, the connecting line of each positioning ear plate 102 in the length direction of the supporting tube 1 is also a straight line parallel to the axis of the supporting tube 1 corresponding to the mounting mode one of the hoop 210.

The more positioning ear plates 102, the better the fixing effect on the hoops 210, and in order to fix the hoops 210 better, the number of the positioning ear plates 102 corresponding to one hoop 210 is at least two, and the positioning ear plates 102 are uniformly distributed along the circumferential direction of the supporting tube 1.

Further, as shown in fig. 2 and 3, the hoop 210 includes at least two arc-shaped hoop strips, and all the arc-shaped hoop strips are circumferentially surrounded along the support tube 1 to form a hoop. If the annular hoop 210 is of an integral structure, such as a strip-shaped material bent into an annular shape with a notch, the annular hoop 210 is assembled to the supporting tube 1 from the notch and fixed, so that the notch is required to be opened and then combined during assembly, the installation is difficult, the structure of the hoop 210 is easy to damage, and therefore the hoop 210 is more ideal to be arranged into a component structure, and in the embodiment, the hoop 210 is formed by two semicircular arc hoops 211.

Further, as shown in fig. 2 and 3, in order to be fixedly mounted with the positioning ear plates 102, a semicircular arc-shaped hoop 211 is disposed between every two adjacent positioning ear plates 102, the semicircular arc-shaped hoop 211 is respectively connected with the two positioning ear plates 102 through extension plates at two ends of the semicircular arc-shaped hoop 211, and the arc-shaped hoop surrounds the support tube 1 along the circumferential direction to form a hoop 210.

As shown in fig. 7, in this embodiment, two positioning ear plates 102 corresponding to one hoop 210 are provided, and the two positioning ear plates 102 are oppositely disposed in the circumferential direction of the hoop 210. The arc-shaped hoops are semicircular hoops 211, one hoop 210 comprises two semicircular hoops 211, and two mounting plates 212 are arranged on one semicircular hoop 211. The more the locating ear plates 102, the better the fixing effect on the anchor ear 210, but the more the number of arc-shaped hoops to be processed correspondingly, the more complex the installation, so the combination of two locating ear plates 102 and two semicircular arc-shaped hoops 211 is a better scheme. For standardization and installation convenience of the anchor ear 210, the number of segments of the guide strip 220 arranged every round is preferably even, that is, the number of mounting plates 212 on one anchor ear 210 is preferably even.

As shown in fig. 2 and 3, in order to avoid interference between the extending plate of the semicircular arc-shaped hoop 211 and the mounting plate 212, the included angle between the connecting line of the mounting plate 212 and the center of the hoop 210 and the plane of the extending plate at the end of the semicircular arc-shaped hoop 211 should not be less than 22.5 °. In this embodiment, the angle between the extension plate at the left end of the semicircular arc-shaped band 211 and the mounting plate 212 adjacent thereto is 22.5 °, and the angle between the extension plate at the right end of the semicircular arc-shaped band 211 and the mounting plate 212 adjacent thereto is 67.5 °.

As shown in fig. 8, the following is a specific embodiment of the manufacture and installation of the wind-resistant vibration band of the present utility model:

1. hoop 210 is fabricated. All hoops 210 are identical and can be prefabricated in standardized modular fashion. For standardization and installation convenience of the anchor ear 210, the number of segments of the guide strip 220 arranged every round is preferably even, that is, the number of mounting plates 212 on one anchor ear 210 is preferably even. In fig. 1, a hoop 210 is provided with 4 mounting plates 212, and a spiral line formed by connecting 4 sections of guide strips 220 end to end can wind around a supporting pipe 1 for one circle.

The guide strip 220 is manufactured. Because the hoops 210 are arranged at equal intervals, the angles of rotation of the upper end and the lower end of each section of the guide lath 220 are the same, so that all the guide laths 220 are uniform and arc-shaped laths, and the guide laths 220 and the mounting holes at the two ends of the guide laths can be directly cut by numerical control blanking.

2. The positioning ear plates 102 are arranged at equal intervals on the two sides of the supporting tube 1 in a straight line, and the ear plate interval is the interval for installing the anchor ear 210.

In this embodiment, 4 mounting plates 212 are disposed on one anchor ear 210, and one side of one anchor ear 210 is connected to 4 guide strips 220. Assuming that the spiral formed by the guide strips 220 is wound around the support tube 1 for one circle on the support tube 1 with the length of 8 meters, and the installation hoops 210 are arranged in equal 4 sections, the interval between each group of hoops 210 and the locating lug plate 102 is 2 meters.

3. The anchor ear 210 is installed. The prefabricated semicircular arc-shaped hoops 211 are installed on each group of positioning ear plates 102 of the supporting tube 1 according to the direction, and are connected and fixed by bolts, rivets or the like.

4. The guide strip 220 is installed. The mounting plate 212 on the anchor ear 210 comprises two mounting lugs arranged on two sides of the anchor ear 210, and the two mounting lugs are respectively connected with two guide strips 220 arranged on two sides of the same anchor ear 210. When the guide strip 220 is installed from one end to the other end along the length direction of the stay tube 1, one end of the guide strip 220 is connected with one installation lug of the installation plate 212 in a semi-positioning state on the hoop 210 on one side, and then is connected with one installation lug of the installation plate 212 which is completely and freely rotated on the hoop 210 on the other side, so that the installation difficulty is low.

The utility model also provides a container crane, which comprises the wind vibration prevention hoop, wherein the wind vibration prevention hoop is arranged on the supporting pipe 1 of the container crane.

The wind-proof vibration hoop is arranged on the supporting pipe of the container crane, so that the wind-proof vibration effect of strong wind at a wharf on the container crane can be effectively reduced, the structural damage of the wind vibration on the container crane is reduced, and the service life of the container crane is prolonged.

The basic principles of the present utility model have been described above in connection with specific embodiments, however, it should be noted that the advantages, benefits, effects, etc. mentioned in the present utility model are merely examples and not intended to be limiting, and these advantages, benefits, effects, etc. are not to be considered as essential to the various embodiments of the present utility model. Furthermore, the specific details disclosed herein are for purposes of illustration and understanding only, and are not intended to be limiting, as the utility model is not necessarily limited to practice with the above described specific details.

The block diagrams of the devices, apparatuses, devices, systems referred to in the present utility model are only illustrative examples and are not intended to require or imply that the connections, arrangements, configurations must be made in the manner shown in the block diagrams. As will be appreciated by one of skill in the art, the devices, apparatuses, devices, systems may be connected, arranged, configured in any manner. Words such as "including," "comprising," "having," and the like are words of openness and mean "including but not limited to," and are used interchangeably therewith. The words "or" and "as used herein refer to the word" or "and are used interchangeably herein unless the context clearly indicates otherwise. The term "such as" as used herein refers to, and is used interchangeably with, the phrase "such as, but not limited to.

It is also noted that in the apparatus, devices and methods of the present utility model, the components or steps may be separated or recombined. These decompositions or recombinations should be regarded as equivalents of the present utility model.

The previous description of the disclosed aspects is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these aspects will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other aspects without departing from the scope of the utility model. Thus, the present utility model is not intended to be limited to the aspects shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

It should be understood that the terms "first", "second", "third", "fourth", "fifth" and "sixth" used in the description of the embodiments of the present utility model are used for more clearly describing the technical solutions, and are not intended to limit the scope of the present utility model.

The foregoing description has been presented for purposes of illustration and description. Furthermore, this description is not intended to limit embodiments of the utility model to the form disclosed herein. Although a number of example aspects and embodiments have been discussed above, a person of ordinary skill in the art will recognize certain variations, modifications, alterations, additions, and subcombinations thereof.

Claims (10)

1. A wind-resistant vibration band, comprising:

the anchor clamps are sleeved on a supporting tube of the equipment and are uniformly distributed along the length direction of the supporting tube;

the mounting plates are uniformly distributed in the circumferential direction of the anchor ear;

the guide battens are obliquely arranged relative to the axis of the stay tube, and the oblique directions are consistent and the oblique angles are the same.

2. The wind-resistant hoop of claim 1 wherein the mounting plate is disposed radially of the hoop, the mounting plate being rotatably coupled to the hoop.

3. The wind-resistant collar of claim 2 wherein said mounting plate includes two mounting ears, one of said mounting ears being adapted to engage one of said guide strips on one side of said collar and the other of said mounting ears being adapted to engage one of said guide strips on the other side of said collar.

4. A wind-resistant vibration band according to claim 3, wherein both of said mounting ears of said mounting plate are symmetrically disposed with respect to the rotational axis of said mounting plate.

5. The wind-resistant vibration band of claim 4, wherein two of said mounting ears of said mounting plate are disposed in a common plane of said mounting plate.

6. The wind-proof vibration hoop according to claim 5, wherein the mounting plate comprises a sheet-shaped mounting plate body and a pin shaft sleeve, the pin shaft sleeve is arranged on one surface of the mounting plate body, two mounting lugs are respectively formed on two sides of the axis of the pin shaft sleeve by the mounting plate body, and the mounting plate is rotationally connected with the hoop through a pin shaft.

7. The wind-proof hoop according to claim 1, wherein the support tube is further provided with positioning lugs for fixing the hoop, and the positioning lugs are uniformly distributed along the circumferential direction of the support tube.

8. The wind-resistant hoop of claim 7, wherein the hoop comprises at least two arcuate strips, all of which are circumferentially looped around the brace to form the hoop.

9. The wind-resistant ear clip of claim 8 wherein one of said arcuate strips is disposed between each two adjacent ones of said positioning ear panels, said arcuate strips being connected to each of said positioning ear panels by extension panels at opposite ends thereof.

10. A container crane comprising a wind-resistant vibration hoop according to any one of claims 1-9, wherein the wind-resistant vibration hoop is mounted on a spreader of the container crane.