CN216616500U - Electromechanical smart integrated supporting system of adorning of annular corridor - Google Patents

Abstract

An electromechanical finish-mounting integrated supporting system for an annular corridor is arranged between an inner ring concrete wall and the upper part of an outer ring masonry brick wall; two concrete ring beams are vertically arranged at intervals on the upper part of the outer ring masonry brick wall; the supporting system comprises an upper bracket and a lower bracket; the upper brackets are arranged at intervals along the annular direction; the upper bracket comprises an upper main beam and a suspender; the suspender is hung below the top plate; the upper main beam is horizontally hung below the hanging rod, one end of the upper main beam is connected with the concrete ring beam above the upper main beam, and the other end of the upper main beam is connected with the inner ring concrete wall body; a wind pipe hanger is hung at the bottom of the upper bracket; the lower brackets are arranged at intervals along the annular direction, one end of each lower bracket is connected with the concrete ring beam below the lower bracket, and the other end of each lower bracket is connected with the inner ring concrete wall body; the bottom of the lower bracket is hung with a hanging plate. The utility model solves the technical problems that the traditional horizontal support cannot be directly fixed on a masonry wall, the multi-layer electromechanical pipelines and the support of the suspended ceiling are difficult to root at the top, the span is large, the number of crossed pipelines is large, and the support and the suspension bracket are messy and waste materials.

Description

Electromechanical smart integrated supporting system of adorning of annular corridor

Technical Field

The utility model belongs to the technical field of constructional engineering, and particularly relates to an electromechanical finish-assembled integrated supporting system for an annular corridor.

Background

A garden theater project, which occupies about 15 ten thousand square meters of floor area and has a total building area of about 10.6 ten thousand square meters, comprises five core theaters A1-A5 and other auxiliary buildings; a1 theater main structure adopts cast-in-place reinforced concrete frame structure, and the roofing adopts the steel truss structure. The center of the A1 theater is provided with a ring-shaped stage and a stand, and the periphery is provided with a ring-shaped corridor. The radius of an inner ring of the annular corridor is 24m, the radius of an outer ring of the annular corridor is 26.8m, and the width of the corridor is 2.8 m; the annular corridor is 4.5 meters high, the ceiling design elevation is 2.7 meters, and the upper part of the corridor ceiling is provided with electromechanical pipelines such as an air conditioner, a fire-fighting bridge, a strong and weak current bridge and the like. The inner ring wall surface of the annular corridor is a concrete wall surface, the outer ring wall surface is mainly a masonry wall surface, the strength of masonry bricks is low, and the horizontal support cannot be directly fixed on the masonry wall body. If each specialty separately considers to be a support hanger, horizontal fixing on a masonry wall is more difficult (concrete blocks or lintels cannot be accurately positioned), and material waste is caused. The supports of the multi-layer electromechanical pipelines and the suspended ceiling are difficult to root at the top, the span is large, the cross is large, and the messy supporting and hanging frames and the waste of materials are easily caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an electromechanical precisely-assembled integrated supporting system for an annular corridor, and aims to solve the technical problems that a traditional horizontal support cannot be directly fixed on a masonry wall, the supporting of a plurality of layers of electromechanical pipelines and a suspended ceiling is difficult to root at the top, the span is large, the supporting and hanging frames are crossed more, and messy supporting and hanging frames and material waste are easily caused.

In order to achieve the purpose, the utility model adopts the following technical scheme.

An annular corridor electromechanical finish-assembled integrated supporting system is arranged between an inner ring concrete wall and the upper part of an outer ring masonry brick wall; a top plate is arranged between the inner ring concrete wall and the top of the outer ring masonry brick wall; two concrete ring beams are vertically arranged at intervals at the upper part of the outer ring masonry brick wall;

the supporting system comprises an upper bracket and a lower bracket; the upper supports are arranged in a group at intervals along the circumferential direction; each upper bracket comprises an upper main beam and a hanging rod; the hanger rod is hung below the top plate; the upper main beam is horizontally hung below the hanging rod, one end of the upper main beam is connected with the concrete ring beam above the upper main beam, and the other end of the upper main beam is connected with the inner ring concrete wall body; an air pipe hanger is hung at the bottom of the upper bracket; the lower supports are arranged in a group at intervals along the annular direction, one end of each lower support is connected with the concrete ring beam below the lower support, and the other end of each lower support is connected with the inner ring concrete wall body; and a hanging plate is hung at the bottom of the lower support.

Preferably, the distance between the adjacent upper brackets is 1.2-1.5 m; the distance between the adjacent lower supports is 1.2 m-1.5 m.

Preferably, the distance between the two concrete ring beams is 0.7-0.9 m.

Preferably, the air pipe hanger comprises a threaded rod and a cross arm; the two threaded rods are respectively connected to the bottom of the upper main beam and are adjustable in the vertical direction; the cross arm is connected between the lower ends of the two threaded rods.

Compared with the prior art, the utility model has the following characteristics and beneficial effects.

1. The support system is divided into an upper support and a lower support, wherein the upper support is fixedly connected to a top plate, and the lower support is fixedly connected to an inner ring concrete wall and a ring masonry brick wall; the support system is well-arranged and reasonably designed, and can reasonably arrange the electromechanical pipelines such as air conditioners, fire-fighting bridges, strong and weak current bridges and the like on the support system, thereby solving the technical problems that the traditional multi-layer electromechanical pipelines and suspended ceilings are difficult to root at the tops, have large span and much cross, and are easy to cause disorder of support and hanging frames and waste of materials.

2. According to the utility model, the concrete ring beam is arranged on the ring masonry brick wall at the connecting position corresponding to the lower support, and the hanging plate is arranged at the bottom of the lower support, so that the technical problem that the horizontal support cannot be directly fixed on the masonry wall is solved, electromechanical and hardbound units share one set of supporting system, and the material is saved, the environment is protected, and the economy is reasonable.

Drawings

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

Fig. 1 is a schematic structural view of the support system of the present invention disposed between an inner ring concrete wall and an upper portion of an outer ring masonry brick wall.

Fig. 2 is a schematic structural view of the air duct hanger of the present invention.

Reference numerals: 1-inner ring concrete wall, 2-outer ring masonry brick wall, 3-top plate, 4-concrete ring beam, 5-upper support, 5.1-upper main beam, 5.2-suspender, 6-lower support, 7-air pipe hanger, 7.1-threaded rod, 7.2-cross arm, 8-first buried plate, 9-second buried plate and 10-hanging plate.

Detailed Description

As shown in fig. 1-2, the supporting system for the electromechanical fine installation integration of the annular corridor is arranged between the inner ring concrete wall 1 and the upper part of the outer ring masonry brick wall 2; a top plate 3 is arranged between the inner ring concrete wall 1 and the top of the outer ring masonry brick wall 2; two concrete ring beams 4 are vertically arranged at intervals at the upper part of the outer ring masonry brick wall 2;

the supporting system comprises an upper bracket 5 and a lower bracket 6; the upper brackets 5 are arranged in a group and are arranged at intervals along the annular direction; each upper support 5 comprises an upper main beam 5.1 and a suspender 5.2; the hanger rod 5.2 is hung below the top plate 3; the upper main beam 5.1 is horizontally hung below the hanging rod 5.2, one end of the upper main beam 5.1 is connected with the concrete ring beam 4 above, and the other end of the upper main beam 5.1 is connected with the inner ring concrete wall 1; an air pipe hanger 7 is hung at the bottom of the upper bracket 5; the lower brackets 6 are arranged in a group at intervals along the circumferential direction, one ends of the lower brackets 6 are connected with the concrete ring beam 4 below, and the other ends of the lower brackets 6 are connected with the inner ring concrete wall 1; a hanging plate 10 is hung at the bottom of the lower brackets 6.

In the embodiment, the distance between the adjacent upper brackets 5 is 1.2-1.5 m; the distance between adjacent lower brackets 6 is 1.2 m-1.5 m.

In the embodiment, the distance between the two concrete ring beams 4 is 0.7-0.9 m.

In this embodiment, the air duct hanger 7 comprises a threaded rod 7.1 and a cross arm 7.2; two threaded rods 7.1 are respectively connected to the bottom of the upper main beam 5.1, and the threaded rods 7.1 are vertically adjustable; the cross arm 7.2 is connected between the lower ends of two threaded rods 7.1.

In this embodiment, a first buried plate 8 is embedded in the upper concrete ring beam 4 and the inner ring concrete wall 1 respectively; and two ends of the upper main beam 5.1 are respectively connected with the first buried plate 8 in a welding manner.

In the embodiment, the distance between the upper main beam 5.1 and the top plate 3 is 1.5-1.8 m; the radius of the inner ring concrete wall body 1 is 24m, and the radius of the outer ring masonry brick wall 2 is 26.8 m.

In this embodiment, the distance between the hanger plate 10 and the lower bracket 6 is 0.2 m.

In the embodiment, a second embedded plate 9 is embedded in the lower concrete ring beam 4 and the inner ring concrete wall 1 respectively; and two ends of the upper main beam 5.1 are respectively connected with the second buried plate 9 in a welding manner.

In this embodiment, the upper main beam 5.1 and the hanger rod 5.2 are integrally formed.

In this embodiment, the suspension rod 5.2 is connected to the bottom of the top plate 3 through an embedded part.

In this embodiment, the upper main beam 5.1 and the lower support 6 are made of finished square steel tubes, the upper main beam 5.1 and the lower support 6 are made of finished supports, integrity is good, reliability is high, and arc-shaped pipeline fixing points in the annular corridor are flexible and adjustable, so that construction is facilitated. The design of the electromechanical pipeline and ceiling integrated supporting system has the advantages of material saving, environmental protection, economy, reasonability, comprehensive coordination of each specialty, clear working procedures, short construction period, avoidance of damage to a masonry wall body and high overall quality.

Claims (4)

1. An annular corridor electromechanical finish-assembled integrated supporting system is arranged between an inner ring concrete wall (1) and the upper part of an outer ring masonry brick wall (2); a top plate (3) is arranged between the inner ring concrete wall (1) and the top of the outer ring masonry brick wall (2); the method is characterized in that: two concrete ring beams (4) are vertically arranged at intervals at the upper part of the outer ring masonry brick wall (2);

the supporting system comprises an upper bracket (5) and a lower bracket (6); the upper supports (5) are arranged in a group and are arranged at intervals along the circumferential direction; each upper support (5) comprises an upper main beam (5.1) and a suspender (5.2); the hanger rod (5.2) is hung below the top plate (3); the upper main beam (5.1) is horizontally hung below the hanging rod (5.2), one end of the upper main beam (5.1) is connected with the concrete ring beam (4) above, and the other end of the upper main beam (5.1) is connected with the inner ring concrete wall body (1); an air pipe hanger (7) is hung at the bottom of the upper bracket (5); the lower supports (6) are arranged in a group at intervals along the circumferential direction, one ends of the lower supports (6) are connected with the concrete ring beam (4) below, and the other ends of the lower supports (6) are connected with the inner ring concrete wall body (1); the bottom of the lower bracket (6) is hung with a hanging plate (10).

2. The annular corridor electromechanical hardbound integrated support system according to claim 1, characterized in that: the distance between the adjacent upper brackets (5) is 1.2-1.5 m; the distance between the adjacent lower supports (6) is 1.2 m-1.5 m.

3. The annular corridor electromechanical hardbound integrated support system according to claim 1, characterized in that: the distance between the two concrete ring beams (4) is 0.7-0.9 m.

4. The annular corridor electromechanical hardbound integrated support system according to claim 1, characterized in that: the air pipe hanger (7) comprises a threaded rod (7.1) and a cross arm (7.2); the two threaded rods (7.1) are respectively connected to the bottom of the upper main beam (5.1), and the threaded rods (7.1) are vertically adjustable; the cross arm (7.2) is connected between the lower ends of the two threaded rods (7.1).

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