CN219622078U - Roof suspension cable clamp with adjustable angle - Google Patents

Abstract

An angle-adjustable roof suspension cable clamp is formed by combining an upper cable clamp mounting body, an upper cable clamp, a lower cable clamp and a lower cable clamp mounting body. The upper cable clamp and the lower cable clamp are combined through bolts to form a suspension cable clamp, an upper half hole and a lower half hole of the suspension cable clamp form a suspension cable jack, and the hole edge of the suspension cable jack is provided with a chamfer. The upper and lower cable clamp mounting bodies are welded on the steel beam, and the suspension cable clamp is provided with a rotation area between the upper and lower cable clamp mounting bodies. The suspension cable clamp rotates to drive the suspension cable jack to link together. The utility model has reasonable design, convenient construction and safe and reliable use. The angle of the suspension cable jack is changed by pulling the suspension cable clamp, the roof suspension cable can be successfully inserted without changing the position of the steel beam, the steel beam lifting times are reduced, the suspension cable insertion is time-saving and labor-saving, the operation efficiency is high, the chamfer of the clamp cable hole orifice cannot crack and wear with the roof suspension cable, and the service life of the roof suspension cable is ensured. The angle-adjustable roof suspension cable clamp is particularly suitable for connecting a roof suspension cable with a roof steel beam.

Description

Roof suspension cable clamp with adjustable angle

Technical Field

The utility model relates to a large-span roof suspension cable connecting structure, in particular to an angle-adjustable roof suspension cable clamp in the structure.

Background

The roof suspension cable and steel beam system is utilized to support the building structure, and the stress balance of the building structure is maintained, so that various special-shaped curved surface modeling of the developed building is formed, and the development mainstream of modern buildings is realized. The main body of the curved roof structure is formed by integrally enabling a plurality of roof suspension ropes to simultaneously pass through a plurality of steel beams and fixing the steel beams on the roof suspension ropes in a suspending way. At present, as roof suspension cables and steel beam structural systems are not long and wide in popularization time, the corresponding specifications are not complete, and the following problems exist in practical application:

1. each roof suspension cable of the curved roof structure is in a vertical concave curve, and a plurality of roof suspension cables penetrate through reserved holes of a plurality of steel beams and are locked and suspended on the roof suspension cables through special clamps. The special fixture is typically welded to the preformed hole of the steel beam. When the steel beam is placed on the support in a slightly inclined way, the cable hole axis of the conventional special fixture is inconsistent with the roof suspension cable axis, and the roof suspension cable cannot pass through the special fixture cable hole in a zigzag way because the special fixture cable hole axis is not adjustable, the roof suspension cable is thicker in diameter and high in strength, so that the steel beam is required to be lifted again and placed at a proper position again, thus the construction time is increased, and the construction cost is increased.

2. The edges of the orifice of the traditional special clamp are not provided with chamfers. When the curve roof suspension cable passes through the cable hole of the special fixture, the curve roof suspension cable is necessarily tangent to the edges of the orifices at the two axial ends of the special fixture, so that the roof suspension cable is always in a state of being bitten by sharp edges of the orifices of the cable hole of the special fixture in operation, and the roof suspension cable is fast in abrasion under the condition that the roof suspension cable is bitten by sharp edges of the orifices of the cable hole, thereby causing damage to the safe use of the roof suspension cable and influencing the service life of the curve roof structure.

Disclosure of Invention

The utility model aims to overcome the defects of the traditional special clamp, and provides the suspension cable clamp which can be used for adjusting the axial angle of the cable hole of the suspension cable clamp in an up-down deflection manner, so that the suspension cable Kong Jiaodu on the steel beam can be adjusted, the roof suspension cable can smoothly pass through the cable hole, the roof suspension cable is inserted in a time-saving and labor-saving manner, and the operation efficiency is high; the rope Kong Kongbian of the suspension rope clamp is provided with a chamfer, the roof suspension rope is not tangent with the suspension rope clamp rope Kong Ruibian and is worn by biting, the use is safe, and the angle-adjustable roof suspension rope clamp capable of guaranteeing the service life of the curved roof structure is provided.

The object of the present utility model can be achieved. The utility model relates to an angle-adjustable roof suspension cable clamp which comprises a roof suspension cable and a steel beam, and is characterized in that: the angle-adjustable roof suspension cable clamp consists of a roof suspension cable, a steel beam and a regulating clamp welded on a steel beam preformed hole, the regulating clamp consists of an upper cable clamp mounting body, an upper cable clamp, a lower cable clamp and a lower cable clamp mounting body,

the upper plane of the upper cable clamp mounting body is square, the bottoms of the transverse, front and rear vertical planes are respectively provided with a lower slope, a cylindrical lower groove is arranged between the two lower slopes along the longitudinal center, the longitudinal left and right sides of the lower groove are respectively provided with an upper convex limiting wall,

the lower cable clamp installation body consists of two symmetrical lower bottom surface structures with the same shape and size and the same size as the upper plane of the upper cable clamp installation body, the upper parts of the transverse front and rear vertical planes of the lower cable clamp installation body are provided with upper sloping surfaces, the longitudinal center between the two upper sloping surfaces is provided with a cylindrical upper groove, the left side and the right side of the upper groove are provided with lower convex limiting walls,

the upper surface of the upper cable clamp is provided with a semi-cylindrical upper convex body along the transverse center, the lower surface is provided with a semi-circular upper half hole along the transverse center, the two sides of the upper convex body and the two sides of the upper half hole are symmetrically extended to form a connecting plate respectively, the connecting plate is vertically provided with a bolt hole, bolts are inserted into the bolt hole, the upper convex body is embedded into a lower groove of the upper cable clamp mounting body, the cylindrical profile of the upper convex body is in fit sliding connection with the cylindrical profile of the lower groove, the vertical surfaces at two sides of the upper convex body are respectively in fit sliding connection with the upper convex body limiting walls at the left side and the right side of the upper cable clamp mounting body,

the cable clamp is characterized in that the cable clamp is installed in a reverse symmetrical mode, the lower surface of the cable clamp is provided with a semi-cylindrical lower protruding body along the transverse center, the upper surface is provided with a semi-circular lower half hole along the transverse center, two sides of the lower protruding body and two sides of the lower half hole are symmetrically extended to form connecting plates respectively, the connecting plates are provided with bolt holes, bolts are inserted into the bolt holes, the lower protruding body is embedded into an upper groove of a lower cable clamp installation body, the cylindrical profile of the lower protruding body is in fit sliding connection with the cylindrical profile of the upper groove, and two vertical planes of the two sides of the upper protruding body are respectively in fit sliding connection with the limiting walls of the lower protruding bodies on the left side and the right side of the lower cable clamp installation body.

The utility model relates to an angle-adjustable roof suspension cable clamp, wherein an upper cable clamp and a lower cable clamp are connected through a connecting plate, a bolt hole and a bolt to form the suspension cable clamp, the vertical axes of the combination of the lower groove, the upper convex body and the lower convex body are positioned on the same vertical line to form a clamp axis, an upper half hole and a lower half hole of the suspension cable clamp are combined to form a circular suspension cable jack, and the common axis of the upper half hole and the lower half hole forms a cable hole axis.

The utility model relates to an angle-adjustable roof suspension cable clamp, wherein the axis of the clamp is crossed with the axis of a cable hole at right angles, the axis of the clamp and the axis of the cable hole are provided with synchronous rotation tracks, the suspension cable jack is linked with a suspension cable clamp, and the suspension cable clamp is provided with a rotation area which rotates along the cylindrical cambered surfaces of an upper groove and a lower groove between an upper cable clamp mounting body and a lower cable clamp mounting body.

The utility model relates to an angle-adjustable roof suspension cable clamp, wherein the edges of the orifices of an upper half hole and a lower half hole are respectively provided with a chamfer.

The angle-adjustable roof suspension cable clamp is different from the prior art in that the angle-adjustable roof suspension cable clamp is formed by combining an upper cable clamp mounting body, an upper cable clamp, a lower cable clamp and a lower cable clamp mounting body. The upper cable clamp and the lower cable clamp are combined through bolts to form a suspension cable clamp, an upper half hole and a lower half hole of the suspension cable clamp form a suspension cable jack, and the edge of an orifice of the suspension cable jack is provided with a chamfer. The upper cable clamp installation body and the lower cable clamp installation body are welded on the steel beam, and the suspension cable clamp is provided with a rotating area along the cylindrical cambered surfaces of the upper groove and the lower groove between the upper cable clamp installation body and the lower cable clamp installation body. The suspension cable jack is linked with the suspension cable clamp. The suspension cable clamp rotates to drive the suspension cable jack to rotate together. The angle-adjustable roof suspension cable clamp is reasonable in design, novel in structure, convenient to construct and safe and reliable to use. The angle of the suspension cable jack is changed by pulling the suspension cable clamp, so that the roof suspension cable can be successfully inserted without changing the position of the steel beam, the steel beam lifting times are reduced, the suspension cable insertion is time-saving and labor-saving, the operation efficiency is high, the chamfer of the cable hole opening of the suspension cable clamp cannot be bitten and worn with the roof suspension cable, and the service life of the roof suspension cable is ensured. The angle-adjustable roof suspension cable clamp is particularly suitable for connecting a roof suspension cable with a roof steel beam.

The angularly adjustable roof suspension cable clamp of the present utility model is further described below with reference to the accompanying drawings. The drawings illustrate the basic structure of the present utility model only by way of illustration, and therefore they show only the structure relevant to the present utility model.

Drawings

FIG. 1 is a schematic view of an application state of an angle-adjustable roof suspension clamp of the present utility model.

Fig. 2 is a schematic view of section a-a of fig. 1 (steel beam and roof suspension cable mounting structure).

Fig. 3 is a detail a of fig. 2.

Fig. 4 is a schematic three-dimensional structure of an angle-adjustable roof suspension clamp.

Fig. 5 is a schematic front view of an angle adjustable roof suspension clamp.

Fig. 6 is a schematic side view of an angularly adjustable roof suspension clamp.

Fig. 7 is a schematic front view of the upper clip mounting body.

Fig. 8 is a side view schematic of the upper clip mounting body.

Fig. 9 is a schematic bottom view of the upper clip mounting body.

Fig. 10 is a schematic front view of the upper cord gripper.

Fig. 11 is a side view schematic of the upper cord clip.

Fig. 12 is a schematic top view of the upper cord clip.

Fig. 13 is a schematic front view of the drop clip.

Fig. 14 is a side view schematic of the drop clip.

Fig. 15 is a schematic top view of the lower cord clip.

Fig. 16 is a schematic front view of the down clip mounting body.

FIG. 17 is a schematic side view of the down clamp mounting body

Fig. 18 is a schematic top view of the lower clip mounting body.

Detailed Description

As shown in fig. 1 to 3, the angle-adjustable roof suspension cable clamp of the utility model is composed of a roof suspension cable 1, a steel beam 2 and a regulating clamp 3 welded on a steel beam reserved hole. The regulating clamp 3 is composed of an upper cable clamp mounting body 31, an upper cable clamp 32, a lower cable clamp 33 and a lower cable clamp mounting body 34.

As shown in fig. 4 to 9, the upper plane of the upper clip mounting body 31 is square, and the bottoms of the horizontal, front and rear vertical planes are respectively provided with a lower slope 311. A cylindrical lower groove 312 is formed between the two sloping surfaces 311 along the longitudinal center. An upper boss limiting wall 313 is provided on each of the left and right longitudinal sides of the lower recess 312.

As shown in fig. 4 to 6, fig. 16 to 18, the lower clip mounting body 34 is composed of two pieces having the same shape and size and symmetrical structure. The overall dimension of the lower bottom surface structure of the lower clip mounting body 34 is equal to the upper planar dimension of the upper clip mounting body 31. The upper part of the transverse front and rear vertical surfaces of the lower cable clip mounting body 34 is provided with an upper slope 341. An upper groove 342 in a cylindrical shape is formed between the two sloping surfaces 341 along the longitudinal center. Lower boss limiting walls 343 are provided on both left and right sides of the upper groove 342.

As shown in fig. 4 to 6 and fig. 10 to 12, the upper surface of the upper cable clip 32 is provided with a cylindrical upper boss 321 along the lateral center, and the lower surface is provided with a semicircular upper half hole 322 along the lateral center. The upper convex body 321 and the outward symmetrical extension parts of the two sides of the upper half hole 322 respectively form a connecting plate 323. The connection plate 323 is vertically provided with a bolt hole 324 through which a bolt is inserted. The upper convex body 321 is embedded in the lower groove 312 of the upper cable clamp mounting body 31, the cylindrical profile of the upper convex body 321 is in fit sliding connection with the cylindrical profile of the lower groove 312, and the vertical surfaces on two sides of the upper convex body 321 are respectively in fit sliding connection with the upper convex body limiting walls 313 on the left side and the right side of the upper cable clamp mounting body 31.

As shown in fig. 4-6 and fig. 13-15, the lower and upper clips 33 and 32 are identical in structural dimension and are installed in opposite symmetry. The lower surface of the lower cable clamp 33 is provided with a cylindrical lower convex body 331 along the transverse center, and the upper surface is provided with a semicircular lower half hole 332 along the transverse center. The outward symmetrical extension parts of the two sides of the lower convex body 331 and the lower half hole 332 respectively form a connecting plate 333, and the connecting plate 333 is provided with a bolt hole 324, and bolts are inserted into the bolt holes. The lower convex body 331 is embedded in the upper groove 342 of the lower cable clamp mounting body 34, the cylindrical profile of the lower convex body 331 is in fit sliding connection with the cylindrical profile of the upper groove 342, and the vertical planes at two sides of the upper convex body 331 are respectively in fit sliding connection with the lower convex body limiting walls 343 at the left side and the right side of the lower cable clamp mounting body 34.

As shown in fig. 4, the upper and lower clamps 32, 33 are connected by connection plates 323, 333, bolt holes 324 and bolts to form a suspension clamp. The vertical axes of the combination of the lower groove 312, the upper groove 342, the upper convex body 321 and the lower convex body 331 are positioned on the same vertical line to form a fixture axis 4. The upper half hole 322 and the lower half hole 332 of the suspension clamp are combined to form a circular suspension cable insertion hole. The common axis of the upper half bore 322 and the lower half bore 332 constitutes the cord bore axis 5.

The roof suspension cable clamp with the adjustable angle comprises a clamp axis 4, a cable hole axis 5, a suspension cable jack and a suspension cable clamp, wherein the clamp axis 4 is intersected with the cable hole axis 5 at a cross right angle, the clamp axis 4 and the cable hole axis 5 have synchronous rotation tracks, and the suspension cable jack is in linkage with the suspension cable clamp. The suspension clamp has a rotation area between the upper and lower clamp mounting bodies 31 and 34 that rotates along the cylindrical arc of the upper and lower grooves 342 and 312.

As shown in fig. 5, 12 and 15, the edges of the openings of the upper half hole 322 and the lower half hole 332 are provided with chamfers 325.

The above examples are merely illustrative of the preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model, and various modifications and improvements made by those skilled in the art to the technical solution of the present utility model should fall within the scope of protection defined by the claims of the present utility model without departing from the design spirit of the present utility model.

Claims (4)

1. The utility model provides an angularly adjustable roofing suspension cable anchor clamps, includes roofing suspension cable (1) and girder steel (2), its characterized in that: the angle-adjustable roof suspension cable clamp consists of a roof suspension cable (1), a steel beam (2) and a regulating clamp (3) welded on a steel beam preformed hole, the regulating clamp (3) consists of an upper cable clamp mounting body (31), an upper cable clamp (32), a lower cable clamp (33) and a lower cable clamp mounting body (34),

the upper plane of the upper cable clamp mounting body (31) is square, the bottoms of the transverse, front and rear vertical planes are respectively provided with a lower slope (311), a cylindrical lower groove (312) is arranged between the two lower slopes (311) along the longitudinal center, the longitudinal left and right sides of the lower groove (312) are respectively provided with an upper convex limiting wall (313),

the lower cable clamp mounting body (34) consists of two symmetrical lower bottom surface structures with the same shape and size and the same size as the upper plane of the upper cable clamp mounting body (31), the upper parts of the transverse, front and rear vertical surfaces of the lower cable clamp mounting body (34) are respectively provided with an upper slope (341), a cylindrical upper groove (342) is arranged between the two upper slopes (341) along the longitudinal center, the left side and the right side of the upper groove (342) are respectively provided with a lower convex limiting wall (343),

the upper surface of the upper cable clamp (32) is provided with a semi-cylindrical upper convex body (321) along the transverse center, the lower surface is provided with a semi-circular upper half hole (322) along the transverse center, two sides of the upper convex body (321) and the upper half hole (322) are symmetrically extended outwards to form a connecting plate (323) respectively, the connecting plate (323) is vertically provided with a bolt hole (324) through which bolts are inserted, the upper convex body (321) is embedded into a lower groove (312) of the upper cable clamp mounting body (31) and the cylindrical profile of the upper convex body (321) is in fit sliding connection with the cylindrical profile of the lower groove (312), the vertical surfaces on two sides of the upper convex body (321) are respectively in fit sliding connection with upper convex body limiting walls (313) on the left side and the right side of the upper cable clamp mounting body (31),

the lower cable clamp (33) and the upper cable clamp 32 are identical in structural dimension and are installed in a mutually opposite and symmetrical mode, a semi-cylindrical lower protruding body (331) is arranged on the lower surface of the lower cable clamp (33) along the transverse center, a semicircular lower half hole (332) is arranged on the upper surface of the lower cable clamp along the transverse center, connecting plates (333) are respectively formed by the two sides of the lower protruding body (331) and the two sides of the lower half hole (332) which extend outwards symmetrically, bolt holes (324) are formed in the connecting plates (333), bolts are inserted into the bolt holes, the lower protruding body (331) is embedded into an upper groove (342) of the lower cable clamp mounting body (34), the cylindrical profile of the lower protruding body (331) is in fit sliding connection with the cylindrical profile of the upper groove (342), and the vertical planes on two sides of the lower protruding body (331) are respectively in fit sliding connection with lower protruding body limiting walls (343) on the left side and the right side of the lower cable clamp mounting body (34).

2. The angularly adjustable roof suspension clamp of claim 1, wherein: go up cable clamp (32), down cable clamp (33) and constitute suspension cable anchor clamps through connecting plates (323, 333), bolt hole (324) and bolted connection, lower recess (312), upper recess (342), go up convex body (321) and lower convex body (331) four the vertical axis of combining the body and be in and constitute anchor clamps axis (4) on same perpendicular, suspension cable anchor clamps's upper half hole (322) and lower half hole (332) combination constitute circular suspension cable jack, the common axis of upper half hole (322) and lower half hole (332) constitutes cable hole axis (5).

3. The angularly adjustable roof suspension clamp of claim 2, wherein: the clamp axis (4) is intersected with the cable hole axis (5) at a cross right angle, the clamp axis (4) and the cable hole axis (5) are provided with synchronous rotation tracks, and the suspension cable clamp is provided with a rotation area which rotates along the cylindrical cambered surfaces of the upper groove (342) and the lower groove (312) between the upper cable clamp mounting body (31) and the lower cable clamp mounting body (34).

4. The angularly adjustable roof suspension clamp of claim 1 or 2, wherein: the edges of the orifices of the upper half hole (322) and the lower half hole (332) are respectively provided with a chamfer (325).