CN211736165U - Steel frame assembly type structure ultra-low energy consumption building external wall panel mounting system - Google Patents

Abstract

The utility model discloses an ultra-low energy consumption building external wall panel installation system of steel frame assembly type structure, including overhead hoist and adjusting support, adjusting support includes vertical rigid coupling and a jib that is T-shaped, the vertical rigid coupling has positioning bolt on the positioning rod, positioning bolt is mutually perpendicular with the jib; the steel wire rope of the lifting device is fixedly connected with the suspension rod, two ends of the positioning rod are respectively connected with a limiting rope, and the adjusting support further comprises pull ropes which are distributed in the opposite direction of the limiting rope. The utility model discloses an ultra-low energy consumption building side fascia mounting system of steel frame assembly type structure can install the ALC slat steadily, improves the smoothness degree of installation.

Description

Steel frame assembly type structure ultra-low energy consumption building external wall panel mounting system

Technical Field

The utility model relates to an ultra-low energy consumption building steel structure wallboard installation technical field, in particular to ultra-low energy consumption building side fascia mounting system of steel frame assembly type structure.

Background

Under the background of global warming and energy shortage, building energy conservation with high energy efficiency and low emission as the core plays a crucial role in realizing energy safety and sustainable development of the country. The ultra-low energy consumption building (also called passive house) is developed and popularized, various passive energy-saving means such as natural ventilation, natural lighting, solar radiation heating and indoor non-heating heat source heating are combined with the high-efficiency energy-saving technology of the building enclosure structure, the dependence on an active mechanical heating and refrigerating system is eliminated to the maximum extent by greatly reducing the heat/cold load of the building on the premise of ensuring the indoor environmental comfort, so that the building heating and refrigerating energy consumption is reduced, meanwhile, renewable energy sources are fully utilized so as to be eliminated from the dependence on the traditional fossil energy sources, and the ultra-low energy consumption building becomes an important means of energy conservation and emission reduction in the world building energy-saving technology leading the country.

The ALC lath has good heat preservation performance and heat insulation performance, and is widely applied to steel frame assembly type structure ultra-low energy consumption buildings. In ordinary assembled building, ALC slat generally is through the external wall panel of slat mounting plate from building inside to outside installation, and the process is comparatively convenient.

However, when the prefabricated building without a construction surface is encountered, the external wall panel cannot be installed from the inside of the building but only from the outside of the building due to the limitation of building design conditions. There is a need for an exterior wall panel installation system that meets the requirements for installing wall panels from the exterior of a building.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an ultralow energy consumption building side fascia mounting system of steel frame assembled structure, it can be installed the ALC slat steadily, improves the smoothness degree of installation.

The above object of the present invention can be achieved by the following technical solutions:

the mounting system for the steel frame assembly type structure ultra-low energy consumption building external wall panel comprises a lifting device and an adjusting support, wherein the adjusting support comprises a T-shaped adjusting rod and a hanger rod which are vertically and fixedly connected, a positioning bolt is vertically and fixedly connected to the adjusting rod, and the positioning bolt is perpendicular to the hanger rod; the steel wire rope of the lifting device is fixedly connected with the suspension rod, two ends of the positioning rod are respectively connected with a limiting rope, and the adjusting support further comprises pull ropes which are distributed in the opposite direction of the limiting rope.

By adopting the technical scheme, the lifting device is arranged at the top of the ultra-low energy consumption building, the positioning rod and the hanger rod are connected with the ALC slat through the positioning bolt, then the steel wire rope of the lifting device is connected with the hanger rod, the two ends of the limiting rod are respectively and fixedly connected with the limiting rope, and the stay rope is also fixedly arranged on the ALC slat in a penetrating way and is relatively positioned below the adjusting bracket; draw the positioning rope by two people subaerial pulling, alone draw the stay cord at the floor that the ALC slat was prepared to take one's place, overhead hoist control ALC slat is at the uniform velocity ascending, and two people are through drawing the balanced ALC slat of positioning rope, and the stay cord that alone draws cooperates the balanced ALC slat of spacing rope simultaneously to this realizes the steady installation of ALC slat, also is convenient for take one's place the ALC slat in corresponding floor.

The utility model discloses further set up to: the end parts of the positioning rod and the hanging rod are fixedly connected with a hanging ring, and the steel wire rope or the positioning rope is fixedly connected with the hanging ring.

By adopting the technical scheme, the steel wire rope or the positioning rope is conveniently bound on the hanging ring, so that the steel wire rope or the positioning rope is connected with the adjusting bracket more quickly.

The utility model discloses further set up to: the lifting device comprises a mounting frame and a winch installed on the mounting frame, the mounting frame comprises a bottom frame and a support frame which are vertically and fixedly connected, the bottom frame is horizontally supported at the top of the ultra-low energy consumption building, the support frame is vertically abutted against a parapet of the ultra-low energy consumption building, and the winch is installed and fixed on the bottom frame.

By adopting the technical scheme, the ALC slat is hoisted by the winch, the mounting frame provides a stable mounting base for the winch, and the stability of the winch during operation is improved.

The utility model discloses further set up to: the mounting panel of L shape is fixed connection on the strut, the perpendicular limit of mounting panel and the parallel rigid coupling of strut, the horizontal limit of mounting panel is taken and is put on parapet's top surface, the upper surface mounting on the horizontal limit of mounting panel has two fixed pulleys.

By adopting the technical scheme, the steel wire rope of the winch winds around the two fixed pulleys to smoothly turn downstairs, and the fixed pulleys are arranged to reduce the friction force applied to the steel wire rope after the steel wire rope turns, so that the hoisting process is more stable.

The utility model discloses further set up to: the lifting device further comprises a counterweight frame, and the counterweight frame is connected with the underframe.

Through adopting above-mentioned technical scheme, the supplementary counter weight that increases the mounting bracket of counter weight frame makes the hoist engine during operation more stable.

The utility model discloses further set up to: the external wall panel installation system further comprises installation components, the installation components comprise guide angle steel and hook head bolts, the guide angle steel is arranged to be two, the upper portion and the lower portion of the guide angle steel are spaced and horizontally and fixedly connected in an outer steel frame of the ultra-low energy consumption building, and the hook head bolts are installed on the ALC slat and are in clamping fit with the guide angle steel.

Through adopting above-mentioned technical scheme, the ALC slat is installed on the outer steel frame after, and the interior facade of ALC slat supports and leans on upper and lower direction angle steel, and the outer facade of ALC slat and the outer facade parallel and level of outer steel frame tighten the gib head bolt, and the gib head part hook of gib head bolt is on upper and lower direction angle steel, and the gib head part of gib head bolt welds with the direction angle steel, accomplishes the stable installation of ALC slat promptly.

To sum up, the utility model discloses following beneficial effect has:

1. by arranging the lifting device and the adjusting bracket, the lifting device controls the ALC lath to ascend at a constant speed, the bracket is adjusted to balance and position the ALC lath in the lifting process, so that the ALC lath is stably installed and is convenient to position the ALC lath on a corresponding floor;

2. by arranging the mounting member, the mounting member is welded or anchored in the ultra-low energy consumption building, and the ALC ribbon board is fixed on the mounting member through the hook bolt, so that the arrangement of the outer wall of the ultra-low energy consumption building is completed.

Drawings

FIG. 1 is a schematic structural view of an embodiment;

FIG. 2 is a schematic structural diagram of the lifting device in the embodiment;

FIG. 3 is a schematic structural view of an adjusting bracket in the embodiment.

In the figure, 1, an ALC lath; 2. a hoisting device; 21. a winch; 22. a mounting frame; 221. a chassis; 222. a support frame; 23. a counterweight frame; 24. mounting a plate; 25. a fixed pulley; 3. adjusting the bracket; 31. a positioning rod; 32. a boom; 33. a hoisting ring; 34. positioning the bolt; 4. a mounting member; 41. a guide angle steel; 42. a hook bolt; 5. a position adjusting rope; 6. pulling a rope; 7. an outer steel frame; 8. a parapet wall.

Detailed Description

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

Example (b): a steel frame assembly type structure ultra-low energy consumption building external wall panel installation system is shown in figure 1 and comprises ALC (autoclaved lightweight concrete) battens 1, a lifting device 2, an adjusting bracket 3 and an installation member 4, wherein the lifting device 2 is installed on the top layer of the ultra-low energy consumption building and used for lifting and transporting the ALC battens 1; the adjusting bracket 3 is arranged on the plate surface of the ALC slat 1 and is used for adjusting the position of the ALC slat 1 in the lifting process; the mounting member 4 is arranged between the ALC ribbon board 1 and an outer steel frame 7 of the ultra-low energy consumption building, so that the ALC ribbon board 1 is stably arranged on the outer steel frame 7.

As shown in fig. 2, the lifting device 2 includes a winch 21, a mounting frame 22 for mounting the winch 21 on the top floor of the ultra-low energy consumption building, and a counterweight bracket 23 connected with the mounting frame 22, the mounting frame 22 includes a bottom frame 221 and a support frame 222 which are vertically fixedly connected, the bottom frame 221 is horizontally supported on the top of the ultra-low energy consumption building, the support frame 222 is vertically supported on a parapet 8 of the ultra-low energy consumption building, the winch 21 is mounted and fixed on the bottom frame 221, the counterweight bracket 23 is also connected with the bottom frame 221, a counterweight is added to the winch 21, and therefore the stability of the winch 21 during operation is improved.

An L-shaped mounting plate 24 is further fixedly connected to the support frame 222, the vertical edge of the mounting plate 24 is fixedly connected with the support frame 222 in parallel, the transverse edge of the mounting plate 24 is placed on the top surface of the parapet wall 8, two fixed pulleys 25 are mounted on the upper surface of the transverse edge, and the steel wire rope of the winch 21 is smoothly turned downstairs around the two fixed pulleys 25.

As shown in fig. 3, the adjusting bracket 3 includes a positioning rod 31 and a suspension rod 32 which are distributed in a T shape, the suspension rod 32 is vertically fixed in the middle of the positioning rod 31, the free ends of the suspension rod 32 and the positioning rod 31 are both fixedly provided with a hanging ring 33, and a steel wire rope of the windlass 21 is bound and fixed on the suspension rod 32. The lifting rings 33 at the two ends of the positioning rod 31 are all bound and fixed with positioning ropes 5. A positioning bolt 34 is also vertically and fixedly connected to the middle position of the positioning rod 31, and the positioning bolt 34 is perpendicular to the suspension rod 32. A through hole is formed in the position, close to the end, of the center line of the ALC slat 1 in a penetrating mode, the positioning bolt 34 penetrates through the through hole, and the ALC slat 1 and the positioning bolt are matched to fix the adjusting bracket 3 on the ALC slat 1.

A through hole is further formed in the position, close to the other end, of the center line of the ALC ribbon board 1, a pull rope 6 is connected in the through hole in a penetrating mode, and the pull rope 6 is distributed towards one side, away from the adjusting bracket 3 (refer to fig. 1).

The mounting member 4 comprises two guide angle steels 41 and hook bolts 42, wherein the two guide angle steels 41 are vertically and symmetrically arranged in the outer steel frame 7 and are welded and fixed with the outer steel frame 7 or fixed on the floor of the ultra-low energy consumption building through expansion bolts. The hook bolt 42 is installed at the corner of the ALC slat 1. After the ALC slat 1 is installed on the outer steel frame 7, the inner vertical face of the ALC slat 1 abuts against the upper and lower guide angle steels 41, the outer vertical face of the ALC slat 1 is flush with the outer vertical face of the outer steel frame 7, the hook head bolt 42 is screwed, the hook head part of the hook head bolt 42 is hooked on the upper and lower guide angle steels 41, and the hook head part of the hook head bolt 42 is welded with the guide angle steels 41, so that the stable installation of the ALC slat 1 is completed.

The concrete hoisting process of the ALC slat 1 comprises the following steps of firstly cleaning a foundation, processing the foundation to be smooth, and popping out the in-position ink line of the ALC slat 1 according to a construction drawing and a typesetting drawing.

Secondly, drilling two through holes at the positions of about 50cm away from the two ends of the length of the ALC ribbon board 1 by using an electric drill, wherein a positioning bolt 34 of the adjusting bracket 3 is installed in one through hole, and is bound on a position adjusting rod 31 of the adjusting component by using a nylon position adjusting rope 5; the nylon pull rope 6 is reversely fixed in the other through hole to prepare for hoisting.

And thirdly, paying off and welding or anchoring the upper and lower guide angle steels 41 along the wall, wherein the adjacent distance of welding spots or anchoring points is 60 cm.

Fourthly, a steel wire rope of the winch 21 is wound around the fixed pulley 25, a lifting hook at the end part is hooked on a lifting ring 33 of the lifting hook, then two persons pull the positioning rope 5 on the ground, and one person pulls the pull rope 6 on a floor where the ALC ribbon board 1 is ready to be in place; the hoist 21 control ALC slat 1 is at the uniform velocity and is risen, and two people balance ALC slat 1 through dragging positioning rope 5, and the stay cord 6 that alone dragged cooperates spacing rope balance ALC slat 1 simultaneously, so also be convenient for take one's place ALC slat 1 corresponding to the floor.

Fifthly, manually drawing the ALC slat 1 to enable the ALC slat 1 to be pressed against the guide angle steel 41, and installing the fixed hook bolt 42 to complete the installation of the ALC slat 1 on the outer steel frame 7.

Sixthly, after the ALC ribbon board 1 is integrally installed, repairing the joint of the ALC ribbon board 1 and the bolt installation hole by using special repairing materials, and filling the gap between the ALC ribbon board 1 and the bottom of the beam or the floor by using special bonding mortar.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (7)

1. The utility model provides an ultra-low energy consumption building side fascia mounting system of steel frame assembled structure which characterized in that: the lifting device comprises a lifting device (2) and an adjusting support (3), wherein the adjusting support (3) comprises a T-shaped positioning rod (31) and a hanging rod (32) which are vertically and fixedly connected, a positioning bolt (34) is vertically and fixedly connected to the positioning rod (31), and the positioning bolt (34) is perpendicular to the hanging rod (32); the steel wire rope of the lifting device (2) is fixedly connected with the suspension rod (32), two ends of the positioning rod (31) are respectively connected with a limiting rope, and the adjusting support (3) further comprises pull ropes (6) which are distributed in the opposite direction of the limiting rope.

2. The steel frame fabricated structural ultra-low energy consumption building external wall panel installation system of claim 1, wherein: the end parts of the positioning rod (31) and the suspension rod (32) are fixedly connected with a hanging ring (33), and the steel wire rope or the positioning rope (5) is fixedly connected with the hanging ring (33).

3. The steel frame fabricated structural ultra-low energy consumption building external wall panel installation system of claim 1, wherein: the lifting device (2) comprises a mounting frame (22) and a winch (21) mounted on the mounting frame (22), the mounting frame (22) comprises an underframe (221) and a support frame (222) which are fixedly connected vertically, the underframe (221) is horizontally supported at the top of the ultra-low energy consumption building, the support frame (222) vertically supports against a parapet wall (8) of the ultra-low energy consumption building, and the winch (21) is mounted and fixed on the underframe (221).

4. The steel frame fabricated structural ultra-low energy consumption building external wall panel installation system of claim 3, wherein: the utility model discloses a parapet wall, including strut (222), the rigid coupling has mounting panel (24) of L shape on strut (222), the perpendicular limit of mounting panel (24) and strut (222) parallel rigid coupling, the horizontal limit of mounting panel (24) is put on the top surface of parapet wall (8), the upper surface mounting on the horizontal limit of mounting panel (24) has two fixed pulleys (25).

5. The steel frame fabricated structural ultra-low energy consumption building external wall panel installation system of claim 3, wherein: the lifting device (2) further comprises a counterweight frame (23), and the counterweight frame (23) is connected with the bottom frame (221).

6. The steel frame fabricated structural ultra-low energy consumption building external wall panel installation system of claim 1, wherein: the external wall panel installation system further comprises an installation component (4), the installation component (4) comprises guide angle steel (41) and hook head bolts (42), the guide angle steel (41) is arranged to be two, the upper portion and the lower portion of the guide angle steel are horizontally fixedly connected in an outer steel frame (7) of the ultra-low energy consumption building, and the hook head bolts (42) are installed on the ALC ribbon board (1) and are in clamping fit with the guide angle steel (41).

7. The steel frame fabricated structural ultra-low energy consumption building external wall panel installation system of claim 6, wherein: the guide angle steel (41) is welded or anchored in the ultra-low energy consumption building.

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