CN212832380U - Stainless steel rope sling component for ocean engineering - Google Patents

Abstract

The utility model discloses a stainless steel cable hoist cable subassembly for ocean engineering, including connecting lifting rope, lifting hook and elastic rope, the annular lifting rope includes that annular lifting rope, setting are in locking hoop and shaping on the annular lifting rope outer wall are in the clavicle ring at both ends about the annular lifting rope, the locking hoop chucking is in on the annular lifting rope. Has the advantages that: the utility model discloses an adopt the connection lifting rope that annular lifting rope of loop configuration constitutes to carry out the ocean engineering and lift by crane, can ensure that this lifting rope can bear great effort of lifting by crane, ensure the security of the process of lifting by crane simultaneously, fine solution there is the problem of interface in current lifting rope, and simultaneously, when lifting by crane columniform object of lifting by crane through the lifting hook, can hang on the couple through hanging the knot after twining several rings on the outer wall of cylinder object of lifting by crane through the elasticity rope, can avoid cylinder object of lifting by crane along endwise slip at the in-process of lifting by crane, ensure the security of the process of lifting by crane.

Description

Stainless steel rope sling component for ocean engineering

Technical Field

The utility model relates to a ocean engineering technology field, concretely relates to stainless steel cable hoist cable subassembly for ocean engineering.

Background

The ocean engineering refers to new construction, reconstruction and extension engineering which aims at developing, utilizing, protecting and recovering ocean resources, and the engineering main body is positioned on one side of a coastline towards the sea.

However, when the existing stainless steel cable sling component is used and connected with a sling, interfaces are mostly arranged at two end parts of the sling, so that the weight of a sling lifting heavy object is greatly limited, and meanwhile, when the cylindrical lifting object is lifted, the cylindrical lifting object can slide in the lifting hook, and certain potential safety hazards exist.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

In order to overcome the prior art not enough, now provide a stainless steel cable hoist cable subassembly for ocean engineering, solved current stainless steel cable hoist cable subassembly when using, connect the lifting rope when fixed, the lifting rope both ends mostly all have the interface, lead to the weight of lifting rope handling heavy object to receive very big restriction to and when the handling to cylindrical handling thing, cylindrical handling thing can slide in the lifting hook is inside, has the problem of certain potential safety hazard.

(II) technical scheme

The utility model discloses a following technical scheme realizes: the utility model provides a stainless steel cable hoist cable subassembly for ocean engineering, including connecting lifting rope, lifting hook and elasticity rope, it includes annular lifting rope, sets up to connect the lifting rope locking hoop and shaping on the annular lifting rope outer wall are in the clavicle ring at both ends about the annular lifting rope, the locking hoop chucking is in on the annular lifting rope, connect the lifting rope below cup joint on the clavicle ring the lifting hook, the lifting hook is the normal close formula lifting hook, the welding has the couple on the lifting hook lateral wall, couple one side is provided with the elasticity rope, the elasticity rope with the lifting hook passes through the screw crimping, an elasticity rope tip shaping has to hang and detains.

By adopting the technical scheme, the connecting lifting rope consisting of the annular lifting ropes with the annular structures is used for lifting in ocean engineering, so that the lifting rope can bear large lifting force, the safety of the lifting process is ensured, the problem that the existing lifting rope has interfaces is well solved, and meanwhile, when a cylindrical lifted object is lifted by the lifting hook, the elastic rope can be wound on the outer wall of the cylindrical lifted object for several circles and then hung on the hook through the hanging buckle, so that the cylindrical lifted object can be prevented from sliding along the axial direction in the lifting process, and the safety of the lifting process is ensured.

Furthermore, the inner wall of the hook is provided with a second anti-skid pad, and the second anti-skid pad is adhered to the hook.

By adopting the technical scheme, the friction force between the lifting hook and the hoisted object can be increased, and the hoisted object is prevented from sliding.

Furthermore, a connecting ring is sleeved on the clavicle ring above the connecting lifting rope, a hanging rod is arranged above the connecting ring and welded with the connecting ring, and the number of the connecting ring and the connecting lifting rope is three.

By adopting the technical scheme, a plurality of hoisted objects can be hoisted simultaneously or a plurality of parts of the hoisted objects can be hoisted simultaneously.

Furthermore, rotation seats are arranged on two sides above the hanging rod and welded with the hanging rod, and rotation shafts are arranged inside the rotation seats and rotatably connected with the rotation seats.

By adopting the technical scheme, the rotating shaft can be ensured to flexibly rotate in the rotating seat, so that the lifting rope has enough freedom degree, and the connecting lifting rope is ensured to be always stretched.

Furthermore, a connecting rod is arranged above the rotating shaft, a rotating groove is formed in the upper portion of the rotating seat and close to the periphery of the connecting rod, and the connecting rod is welded with the rotating shaft.

Through adopting above-mentioned technical scheme, can ensure the connecting rod with the axis of rotation is firmly connected.

Furthermore, a lifting ring is arranged above the connecting rod and welded with the connecting rod, and a first anti-slip pad is bonded on the upper portion of the inner wall of the lifting ring.

Through adopting above-mentioned technical scheme, play rings and outside handling instrument and be connected, the slipmat plays skid-proof effect together.

(III) advantageous effects

Compared with the prior art, the utility model, following beneficial effect has:

1. in order to solve the problem that when the existing stainless steel cable sling component is used and a connecting sling is fixed, interfaces are mostly arranged at two end parts of the sling, so that the weight of heavy objects lifted by the sling is greatly limited;

2. for solving current stainless steel cable hoist cable subassembly when cylindrical handling thing handling, cylindrical handling thing can slide in the lifting hook is inside, has the problem of certain potential safety hazard, the utility model discloses when lifting cylindrical lifting thing through the lifting hook, can hang on the couple through hanging the knot after twining several rings on the outer wall of cylindrical lifting thing through the elasticity rope, can avoid the cylinder to lift up the thing and lift up the in-process along endwise slip, ensure the security of the process of lifting by crane.

Drawings

Fig. 1 is a front view of a stainless steel cable sling assembly for marine applications according to the present invention;

FIG. 2 is a front cross-sectional view of a connecting sling of a stainless steel cable sling assembly for use in marine applications;

fig. 3 is a schematic view of the connection relationship between the lifting ring, the first anti-slip mat, the connecting rod, the rotating seat, the rotating shaft and the lifting rod in the stainless steel cable sling component for ocean engineering.

The reference numerals are explained below:

1. lifting a lifting ring; 2. a first anti-skid pad; 3. a connecting rod; 4. a rotating seat; 5. a rotating groove; 6. a rotating shaft; 7. a boom; 8. a connecting ring; 9. connecting a lifting rope; 901. a looped lifting rope; 902. a locking band; 903. a clavicular ring; 10. a hook; 11. hooking; 12. a second anti-skid pad; 13. an elastic cord; 14. and (7) hanging and buckling.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in fig. 1-3, the stainless steel cable sling assembly for ocean engineering in the present embodiment comprises a connecting sling 9, a hook 10 and an elastic rope 13, wherein the connecting sling 9 comprises an annular sling 901, a locking hoop 902 arranged on the outer wall of the annular sling 901, and clavicle rings 903 formed at the upper and lower ends of the annular sling 901, the locking hoop 902 is clamped on the annular sling 901, the hook 10 is sleeved on the clavicle ring 903 below the connecting sling 9, the hook 10 is a normally closed type hook, a hook 11 is welded on one side wall of the hook 10, the elastic rope 13 is arranged on one side of the hook 11, the elastic rope 13 is in screw press-connection with the hook 10, a hanging buckle 14 is formed on one end of the elastic rope 13, and the connecting sling 9 formed by the annular sling 901 with an annular structure is used for ocean engineering hoisting, so as to ensure that the sling can bear a large hoisting force and ensure the safety of the hoisting process, the problem that the existing lifting rope has an interface is well solved, and meanwhile, when a cylindrical lifting object is lifted by the lifting hook 10, the elastic rope 13 can be wound on the outer wall of the cylindrical lifting object for several circles and then hung on the hook 11 through the hanging buckle 14, so that the cylindrical lifting object can be prevented from sliding along the axial direction in the lifting process, and the safety of the lifting process is ensured.

The inner wall of the hook 11 is provided with the non-slip mat II 12, the non-slip mat II 12 is bonded with the hook 11, the friction force between the lifting hook 10 and a lifted object can be increased, and the lifted object is prevented from sliding.

The collar bone 903 above the connecting lifting rope 9 is sleeved with the connecting ring 8, the suspender 7 is arranged above the connecting ring 8, the suspender 7 is welded with the connecting ring 8, the number of the connecting ring 8 and the connecting lifting rope 9 is three, and a plurality of hoisted objects or a plurality of positions of the hoisted objects can be ensured to be hoisted simultaneously.

The rotary seat 4 is arranged on two sides above the suspender 7, the rotary seat 4 is welded with the suspender 7, the rotary shaft 6 is arranged in the rotary seat 4, the rotary shaft 6 is rotatably connected with the rotary seat 4, the rotary shaft 6 can be flexibly rotated in the rotary seat 4, and then the lifting rope has enough freedom, and the lifting rope 9 is ensured to be connected and extended all the time.

Connecting rod 3 is provided with above 6 of axis of rotation, rotates 4 tops of seat and is close to the peripheral shaping of connecting rod 3 and has a rotation groove 5, and connecting rod 3 and axis of rotation 6 welding can ensure connecting rod 3 and axis of rotation 6 firm connection.

Connecting rod 3 top is provided with rings 1, and rings 1 and connecting rod 3 welding play rings 1 inner wall top bonding has slipmat one 2, and rings 1 is connected with outside handling instrument, and slipmat one 2 plays skid-proof effect.

The specific implementation process of this embodiment is as follows: when the stainless steel cable sling component is used, the hoisting ring 1 is connected with a hoisting machine, when an object needs to be hoisted, the object can be hoisted by the hoisting rings 10 at two sides, when the object needs to be hoisted, the object needs to be hoisted simultaneously, the object can be hoisted by the three hoisting rings 10, so that the balanced stress in the hoisting process is ensured, when the object needs to be hoisted, the cylindrical object can be wound on the outer wall of the cylindrical object through the elastic rope 13 for a plurality of circles and then hung on the hook 11 through the hanging buckle 14, the cylindrical object can be prevented from sliding along the axial direction in the hoisting process, the safety in the hoisting process is ensured, in the hoisting process, the rotating shaft 6 of the hoisting rope can flexibly rotate in the rotating seat 4, the, the connecting lifting rope 9 formed by the annular lifting ropes 901 adopting the annular structures is used for lifting in ocean engineering, so that the lifting rope can bear large lifting force, the safety of the lifting process is ensured, and the problem that the existing lifting rope has interfaces is well solved.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and are not intended to limit the spirit and scope of the present invention. Without departing from the design concept of the present invention, various modifications and improvements made by the technical solution of the present invention by those skilled in the art should fall into the protection scope of the present invention, and the technical contents claimed by the present invention have been fully recorded in the claims.

Claims (6)

1. A stainless steel rope sling assembly for marine engineering, characterized by: including connecting lifting rope (9), lifting hook (10) and elasticity rope (13), it is in to connect lifting rope (9) including annular lifting rope (901), setting locking hoop (902) and the shaping on annular lifting rope (901) outer wall are in clavicle ring (903) at both ends about annular lifting rope (901), locking hoop (902) chucking is in on annular lifting rope (901), it has cup jointed on clavicle ring (903) to connect lifting rope (9) below lifting hook (10), lifting hook (10) are normal close formula lifting hook, the welding has couple (11) on lifting hook (10) a lateral wall, couple (11) one side is provided with elasticity rope (13), elasticity rope (13) with lifting hook (10) are through the screw crimping, elasticity rope (13) one end shaping has buckle (14).

2. A stainless steel rope sling assembly for marine engineering as claimed in claim 1, wherein: and a second anti-skid pad (12) is arranged on the inner wall of the hook (11), and the second anti-skid pad (12) is adhered to the hook (11).

3. A stainless steel rope sling assembly for marine engineering as claimed in claim 2, wherein: connect lifting rope (9) top the go up the cup joint go-between (8) in collar bone ring (903), go-between (8) top is provided with jib (7), jib (7) with go-between (8) welding, go-between (8) and connect the number of lifting rope (9) and be three.

4. A stainless steel rope sling assembly for marine engineering as claimed in claim 3, wherein: the suspension rod (7) top both sides are provided with and rotate seat (4), rotate seat (4) with suspension rod (7) welding, it is provided with axis of rotation (6) to rotate seat (4) inside, axis of rotation (6) with it rotates to be connected to rotate seat (4).

5. A stainless steel rope sling assembly for marine engineering as claimed in claim 4, wherein: the connecting rod (3) is arranged above the rotating shaft (6), the rotating seat (4) is close to the periphery of the connecting rod (3), a rotating groove (5) is formed in the periphery of the connecting rod (3), and the connecting rod (3) is welded with the rotating shaft (6).

6. A stainless steel rope sling assembly for marine engineering as claimed in claim 5, wherein: the anti-skid device is characterized in that a lifting ring (1) is arranged above the connecting rod (3), the lifting ring (1) is welded with the connecting rod (3), and a first anti-skid pad (2) is bonded on the upper portion of the inner wall of the lifting ring (1).

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