CN219671666U - Civil engineering steel construction buries piece - Google Patents

Abstract

The utility model relates to a civil engineering steel structure embedded part, which comprises a rod-shaped embedded rod and a mounting plate, wherein a chute is arranged on the mounting plate, a sliding plate is arranged in the chute in a sliding manner, a limiting plate positioned outside the chute is arranged on the sliding plate, and the limiting plate is mutually perpendicular to the sliding plate; an adjusting hole for allowing the end of the embedded rod to pass through is formed in the mounting plate in a penetrating manner, and the length direction of the adjusting hole extends along the sliding direction of the sliding plate; the sliding plate is penetrated with a plurality of perforations, the perforations are communicated with the adjusting holes, and the perforations are used for allowing the end parts of the embedded rod to pass through; and the end part of the embedded rod is in threaded connection with a fastening nut. The utility model has the effect of ensuring the stability of the embedded rod inserted in the pouring area along the direction vertical to the opening surface of the pouring area.

Description

Civil engineering steel construction buries piece

Technical Field

The utility model relates to the technical field of embedded parts, in particular to a civil engineering steel structure embedded part.

Background

The embedded part refers to a part in which a member is embedded in a building in advance by means of concrete casting in civil construction so as to overlap with an upper structure. The embedded parts of the steel structure are firm and reliable, so that the embedded parts are widely applied to civil engineering construction.

At present, when the steel structure embedded part is constructed, a casting area is firstly surrounded by the surrounding baffle in a to-be-constructed area, then the steel structure embedded part is inserted into the casting area, then concrete is poured into the casting area, after the concrete in the casting area is solidified, the surrounding baffle is removed, and at the moment, the steel structure embedded part is smoothly fixed in the casting area.

However, if the steel structure embedded part is in a rod-shaped structure, it is difficult for constructors to ensure that the steel structure embedded part is stably inserted in the pouring area along the direction perpendicular to the opening surface of the pouring area.

Disclosure of Invention

The utility model provides a civil engineering steel structure embedded part, which has the effect of ensuring that a rod-shaped steel structure embedded part is stably inserted in a pouring area along the direction perpendicular to the opening surface of the pouring area.

The utility model provides a civil engineering steel structure embedded part, which adopts the following technical scheme:

the civil engineering steel structure embedded part comprises a rod-shaped embedded rod and also comprises a mounting plate, wherein a chute is arranged on the mounting plate, a sliding plate is arranged in the chute in a sliding manner, a limiting plate positioned outside the chute is arranged on the sliding plate, and the limiting plate is mutually perpendicular to the sliding plate; an adjusting hole for allowing the end of the embedded rod to pass through is formed in the mounting plate in a penetrating manner, and the length direction of the adjusting hole extends along the sliding direction of the sliding plate; the sliding plate is penetrated with a plurality of perforations, the perforations are communicated with the adjusting holes, and the perforations are used for allowing the end parts of the embedded rod to pass through; and the end part of the embedded rod is in threaded connection with a fastening nut.

By adopting the technical scheme: when the embedded rod is required to be inserted into the pouring area along the direction perpendicular to the opening surface of the pouring area, firstly placing the mounting plate on the top of the enclosure, then pulling out the sliding plate in the direction away from the mounting plate, moving the limiting plate to the outside of the enclosure, and limiting the mounting plate through the limiting plate, so that the mounting plate is not easy to fall into the pouring area; at the moment, constructors can pass through the end parts of the embedded bars on the adjusting holes, finally, the fastening nuts are screwed on the end parts of the embedded bars, and the embedded bars can be pressed and fixed on the mounting plate under the action of the fastening nuts; after the pouring work of the concrete is finished, the fastening nut is screwed out from the end part of the embedded rod, and finally the mounting plate is taken out integrally; when installing the embedded rod, still accessible passes perforation and the regulation hole of suitable position with embedded rod tip in proper order, screws fastening nut at embedded rod tip at last again, just can realize carrying out spacing fixedly with the slide this moment to can ensure limiting plate and enclose each other tightly that keep off the lateral wall, strengthened the spacing effect to the mounting panel, finally ensured to insert the stability of establishing the embedded rod in pouring the district along the direction of perpendicular to pouring district opening surface.

Preferably, the sliding plate is provided with a stop block positioned in the sliding groove, and the stop block slides in the sliding groove along with the sliding plate; the mounting plate is also provided with a baffle plate, and the baffle plate is positioned on a path along which the baffle plate moves along the direction of separating from the chute; the baffle is provided with a through hole which is only used for the sliding plate to pass through, and the baffle is used for being contacted with the stop block.

By adopting the technical scheme: when the sliding plate is pulled in the direction away from the mounting plate, the stop block gradually approaches the baffle plate along with the sliding plate until the stop block moves to be in contact with the baffle plate, and at the moment, the situation that the sliding plate is completely separated from the sliding groove can be prevented under the check of the baffle plate, so that the maximum sliding range of the sliding plate is limited.

Preferably, the baffle is slidably disposed on the mounting plate along a sliding direction perpendicular to the sliding plate.

Preferably, the baffle is provided with a handle positioned outside the mounting plate.

Preferably, a return spring is arranged in the sliding groove, and the return spring stretches along the sliding direction of the sliding plate; one end of the return spring is connected with the stop block, and the other end of the return spring is used for abutting against the baffle plate; the return spring is used for pushing the sliding plate to move towards the direction close to the sliding groove.

Preferably, the mounting plate comprises a first connecting plate and a second connecting plate which are symmetrically arranged; the screw rod is arranged on the first connecting plate and the second connecting plate, an adjusting pipe with hollow inside is arranged between the first connecting plate and the second connecting plate, reverse internal threads are arranged on the inner side walls of the two ends of the adjusting pipe, and the screw rod is screwed into the adjusting pipe from the two ends of the adjusting pipe through the internal threads.

Preferably, the outer side wall of the limiting plate is provided with a rubber pad which is used for being mutually attached to the outer side wall of the enclosure.

Preferably, a grouting opening is formed between the first connecting plate and the second connecting plate in a surrounding mode.

In summary, the present utility model includes at least one of the following beneficial technical effects:

the stability of the embedded rod inserted in the pouring area along the direction perpendicular to the opening surface of the pouring area is ensured;

the sliding adjustment is carried out on the position of the sliding plate, so that the sliding plate can be adapted to the use requirements of pouring areas with different specifications;

the first connecting plate and the second connecting plate are moved to the directions close to each other or far away from each other by rotating the adjusting pipe, so that the requirement of adjusting the installation position of the embedded rod can be met.

Drawings

FIG. 1 is a schematic view of the overall construction of an embodiment of the present utility model mounted on a surround;

FIG. 2 is a schematic view showing the overall structure of the embedded rod and the fastening nut;

FIG. 3 is a schematic exploded view of a partial structure at the highlighting adjustment tube of FIG. 1;

FIG. 4 is an exploded view showing the partial structure of the slide plate and the runner.

Reference numerals illustrate: 1. embedding a rod; 2. a mounting plate; 20. a chute; 21. an adjustment aperture; 22. a first connection plate; 23. a second connecting plate; 24. a screw; 25. a grouting port; 3. a slide plate; 30. perforating; 31. a stop block; 4. a limiting plate; 5. a fastening nut; 6. a baffle; 60. a through hole; 61. a handle; 7. a return spring; 8. an adjusting tube; 80. an internal thread; 9. and a rubber pad.

Description of the embodiments

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

The embodiment of the utility model discloses a civil engineering steel structure embedded part.

Referring to fig. 1 and 2, the civil engineering steel structure embedded part comprises a plurality of long rod-shaped steel structure embedded rods 1, external threads are arranged on the outer side walls of the end parts of the embedded rods 1, and the end parts of the embedded rods 1 are connected with fastening nuts 5 through the external threads. The mounting plate 2 is also made of a steel structure, the mounting plate 2 comprises a first connecting plate 22 and a second connecting plate 23 which are symmetrically arranged, screw rods 24 are fixedly welded on the opposite side walls of the first connecting plate 22 and the second connecting plate 23, and the number of the screw rods 24 can be increased or decreased according to actual requirements.

As shown in fig. 3, a plurality of adjusting pipes 8 having hollow interiors are provided between the first connecting plate 22 and the second connecting plate 23, and the adjusting pipes 8 are coaxially provided with respective opposite side screws 24. The inner side walls at two ends of the adjusting pipe 8 are provided with reverse internal threads 80, the screw rods 24 positioned at two sides of the adjusting pipe 8 are respectively inserted into the adjusting pipes 8 which are opposite to each other, and the screw rods 24 are in threaded connection with the adjusting pipe 8 through the internal threads 80. Since the female screws 80 at both ends of the adjustment tube 8 are disposed in opposite directions, the first and second connection plates 22 and 23 at both sides of the adjustment tube 8 are moved in directions approaching or separating from each other by rotating the adjustment tube 8. In this case, the distance between the first connection plate 22 and the second connection plate 23 can be adjusted.

As shown in fig. 3, the first connecting plate 22 and the second connecting plate 23 are formed with a grouting opening 25 penetrating up and down in a surrounding manner, the grouting opening 25 is positioned at the center of the mounting plate 2, and concrete can be poured into a pouring area smoothly and uniformly in the later period conveniently through the grouting opening 25.

As shown in fig. 3 and 4, the first connecting plate 22 and the second connecting plate 23 are respectively provided with a chute 20, two sliding plates 3 which are oppositely arranged are slidably arranged in the chute 20, and the sliding plates 3 positioned in the same chute 20 are respectively positioned at two sides of the chute 20. One end of the sliding plate 3 extends out of the sliding groove 20, a limiting plate 4 is fixedly arranged on the sliding plate 3 extending out of the sliding groove 20, the limiting plate 4 is perpendicular to the sliding plate 3, and a rubber pad 9 which is used for being mutually attached to the outer side wall of the enclosure is fixedly adhered to the outer side wall of the limiting plate 4.

As shown in fig. 3 and 4, a stopper 31 is fixedly arranged on the slide plate 3 and positioned in the slide groove 20, and the stopper 31 slides in the slide groove 20 along with the slide plate 3. Two baffles 6 are arranged on the first connecting plate 22 and the second connecting plate 23, and the baffles 6 are respectively positioned at two sides of the opening of the chute 20. The baffle 6 is located on the path that the respective opposite stoppers 31 move along the direction of separating from the chute 20, and through holes 60 through which only the respective opposite sliding plates 3 can pass are formed in the baffle 6, and the baffle 6 is used for contacting with the stoppers 31.

When the slide plate 3 is pulled away from the mounting plate 2, the stop block 31 gradually approaches the baffle plate 6 at one side along with the slide plate 3 until the stop block 31 moves to be in contact with the baffle plate 6, and at the moment, the slide plate 3 can be prevented from being completely separated from the sliding groove 20 under the stop of the stop block 31, so that the maximum sliding range of the slide plate 3 is limited.

As shown in fig. 3 and 4, the baffle 6 is slidably disposed on the mounting plate 2 along a sliding direction perpendicular to the sliding plate 3, the lower end of the baffle 6 is inserted into the chute 20, the upper end of the baffle 6 penetrates out from the outer side wall of the mounting plate 2, and a handle 61 is fixedly mounted on the top side wall of the baffle 6 after penetrating out of the mounting plate 2, so that the handle 61 is convenient for constructors to push and pull the baffle 6. By withdrawing the shutter 6 from the mounting plate 2, the slide plate 3 can now be slid out of the respective slide slot 20.

As shown in fig. 3 and 4, a return spring 7 is further provided in the chute 20 between the baffle 6 and the stopper 31, and the return spring 7 expands and contracts in the sliding direction of the slide plate 3. One end of the return spring 7 is fixedly connected with the stop block 31, and the other end of the return spring 7 is mutually abutted against the inner side walls of the baffle plates 6 adjacent to the return spring. The return spring 7 is used for pushing the sliding plates 3 where the return spring 7 is located to move towards the direction close to the sliding groove 20, and when the limiting plate 4 is in contact with the outer side wall of the enclosure, the limiting plate 4 can be further pressed on the outer side wall of the enclosure under the action of the return spring 7, so that the stability of the limiting plate 4 can be ensured.

As shown in fig. 3 and 4, the first connecting plate 22 and the second connecting plate 23 are vertically penetrated with an adjusting hole 21 for the end of the embedded rod 1 to pass through, and the length direction of the adjusting hole 21 extends along the sliding direction of the sliding plate 3. The slide plate 3 is also provided with a plurality of through holes 30 which are vertically penetrated, and the through holes 30 are sequentially arranged at intervals along the sliding direction of the slide plate 3. The perforation 30 communicates with the adjustment hole 21, and the perforation 30 is also used for the end of the embedded rod 1 to pass through.

Through penetrating the perforation 30 and the regulation hole 21 of suitable position in proper order with embedded bar 1 tip, screw fastening nut 5 again at embedded bar 1 tip at last, just can realize carrying out spacing fixed with slide 3 this moment to can ensure limiting plate 4 and enclose and keep off mutual the tight of lateral wall, strengthen the spacing effect to mounting panel 2, finally ensured along the direction of perpendicular to pouring the district opening surface and inserted the stability of establishing embedded bar 1 in pouring the district.

The implementation principle is as follows:

when the embedded rod 1 is required to be inserted into the pouring area along the direction perpendicular to the opening surface of the pouring area, the mounting plate 2 is placed at the top of the enclosure, then the sliding plate 3 is pulled out along the direction far away from the mounting plate 2, the limiting plate 4 is moved to the outside of the enclosure, and the mounting plate 2 is limited through the limiting plate 4, so that the mounting plate 2 is not easy to fall into the pouring area. At this time, constructors can pass through the end part of the embedded rod 1 on the adjusting hole 21, finally screw the fastening nut 5 on the end part of the embedded rod 1, and press and fix the embedded rod 1 on the mounting plate 2 under the action of the fastening nut 5. After the pouring work of the concrete is finished, the fastening nut 5 is screwed out from the end part of the embedded rod 1, and finally the mounting plate 2 is taken out integrally.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (8)

1. The utility model provides a civil engineering steel construction buries, is embedded bar (1), its characterized in that including being the shaft-like: the sliding plate is characterized by further comprising a mounting plate (2), wherein a sliding groove (20) is formed in the mounting plate (2), a sliding plate (3) is arranged in the sliding groove (20), a limiting plate (4) positioned outside the sliding groove (20) is arranged on the sliding plate (3), and the limiting plate (4) is perpendicular to the sliding plate (3); an adjusting hole (21) for allowing the end part of the embedded rod (1) to pass through is formed in the mounting plate (2), and the length direction of the adjusting hole (21) extends along the sliding direction of the sliding plate (3); a plurality of perforations (30) are communicated with the sliding plate (3), the perforations (30) are communicated with the adjusting holes (21), and the perforations (30) are used for allowing the end parts of the embedded rods (1) to pass through; the end part of the embedded rod (1) is connected with a fastening nut (5) through threads.

2. A civil engineering steel building burial according to claim 1, wherein: the sliding plate (3) is provided with a stop block (31) positioned in the sliding groove (20), and the stop block (31) slides in the sliding groove (20) along with the sliding plate (3); the mounting plate (2) is also provided with a baffle plate (6), and the baffle plate (6) is positioned on a path along which the stop block (31) moves along the direction of separating from the chute (20); the baffle (6) is penetrated with a through hole (60) which can only be penetrated by the sliding plate (3), and the baffle (6) is used for contacting with the stop block (31).

3. A civil engineering steel building burial according to claim 2, wherein: the baffle plate (6) is arranged on the mounting plate (2) in a sliding way perpendicular to the sliding direction of the sliding plate (3).

4. A civil engineering steel building burial as claimed in claim 3, wherein: the baffle (6) is provided with a handle (61) positioned outside the mounting plate (2).

5. A civil engineering steel construction borehole in accordance with claim 4 wherein: a return spring (7) is arranged in the sliding groove (20), and the return spring (7) stretches and contracts along the sliding direction of the sliding plate (3); one end of the return spring (7) is connected with the stop block (31), and the other end of the return spring (7) is used for abutting against the baffle (6); the return spring (7) is used for pushing the sliding plate (3) to move towards the direction approaching the sliding groove (20).

6. A civil engineering steel building burial according to claim 1, wherein: the mounting plate (2) comprises a first connecting plate (22) and a second connecting plate (23) which are symmetrically arranged; the novel adjustable adjusting device is characterized in that screw rods (24) are arranged on the first connecting plate (22) and the second connecting plate (23), an adjusting pipe (8) with hollow inside is arranged between the first connecting plate (22) and the second connecting plate (23), reverse internal threads (80) are arranged on inner side walls of two ends of the adjusting pipe (8), and the screw rods (24) are screwed into the adjusting pipe (8) from two ends of the adjusting pipe (8) through the internal threads (80) respectively.

7. A civil engineering steel building burial according to claim 1, wherein: and a rubber pad (9) which is mutually attached to the outer side wall of the enclosure is arranged on the outer side wall of the limiting plate (4).

8. A civil engineering steel construction borehole in accordance with claim 6 wherein: a grouting opening (25) is formed between the first connecting plate (22) and the second connecting plate (23) in a surrounding mode.