CN210887422U - Assembled building engineering fire fighting permanent temporary combination system - Google Patents

Abstract

The utility model provides an assembled building engineering fire control faces combination system forever relates to building construction fire extinguishing system's technical field. The assembly type building engineering fire fighting permanent temporary combination system comprises a main pipe, branch pipes, fire hydrants, a first structural beam and prefabricated laminated slabs; the lower extreme of being responsible for is connected with the total play water piping in the ground in the building, and the upper end of being responsible for passes prefabricated superimposed sheet and rises to the working face, is responsible for and can passes the reservation entrance to a cave of prefabricated superimposed sheet, and the branch pipe is worn to establish in the first structure roof beam in the building to the play water end of branch pipe connects the fire hydrant, and the bearing wall in the building is connected to the fire hydrant. The problem of during construction, need set up twice fire extinguishing system, with high costs, operating personnel's installation cost is high is solved. The utility model discloses a total outlet pipe on ground in the lower extreme of being responsible for is connected building, and the upper end of being responsible for is passed and is reserved entrance to a cave connecting branch pipe, and first structure roof beam internal fixation is worn to establish by the branch pipe, and the fire hydrant is connected on the bearing wall in the building, and the fire extinguishing system is an installation, practices thrift expense and manpower.

Description

Assembled building engineering fire fighting permanent temporary combination system

Technical Field

The utility model belongs to the technical field of the technique of construction fire extinguishing system and specifically relates to a combination system is faced forever in assembly type building engineering fire control.

Background

In the construction process of a construction project, a temporary fire-fighting water system needs to be set according to the standard requirements of engineering fire-fighting standards, and when the fire-fighting system is built, the temporary fire-fighting system is usually built in a specified area outside a building to avoid influencing facilities in the building, so that the construction operation can be safely carried out.

Among the above-mentioned prior art, when setting up interim fire extinguishing system, for satisfying the user demand on the scene, need purchase a large amount of fire-fighting equipment of interim usefulness and supply the field installation to use, treat building construction back that finishes, need dismantle these interim fire extinguishing system, then install formal fire extinguishing system in the building again to the user uses.

Although the temporarily built fire fighting systems are low in cost, the cost of the fire fighting systems is wasted due to the large number of the temporarily built fire fighting systems; and this fire extinguishing system needs the operation personnel to install twice, has also caused the increase of cost of labor.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an assembly type building engineering fire control faces combination system forever to solve existence among the prior art, in the project work progress of building, need build interim fire extinguishing system outside the building structure or on the outrigger earlier, treat that building construction finishes the back, set up formal fire extinguishing system in the building, cause the waste of secondary installation fire extinguishing system cost, and also increased secondary operation personnel's installation cost's technical problem.

The utility model provides an assembled building engineering fire fighting permanent temporary combination system, which comprises a main pipe, a branch pipe, a fire hydrant, a first structural beam and a prefabricated laminated slab;

the lower end of the main pipe is connected with a main water outlet pipe on the ground in the building, the upper end of the main pipe penetrates through the prefabricated composite slab and rises to the working surface, the main pipe can penetrate through a reserved hole of the prefabricated composite slab,

the branch pipe penetrates through the first structural beam in the building, the water outlet end of the branch pipe is connected with a fire hydrant, and the fire hydrant is connected on a bearing wall in the building.

Furthermore, the first structural beam is provided with a limiting hole, and the branch pipe is arranged in the limiting hole in a penetrating mode.

Furthermore, a limiting sleeve is connected in the limiting hole, and the branch pipe penetrates through the limiting sleeve.

Furthermore, the diameter of the limiting hole is larger than that of the branch pipe.

Furthermore, a reinforcing pad is connected in the limiting hole.

Further, the structure also comprises a second structural beam;

the second structural beam is connected with the termination end of the first structural beam, and the second structural beam is arranged on the side face of the branch pipe.

Furthermore, the end face of the inner side, far away from the branch pipe, of the second structure beam is connected with a reinforcing batten.

Furthermore, the outer side end face of the reinforced batten is provided with a batten convex end.

Furthermore, the end face of the inner side, close to the branch pipe, of the second structure beam is connected with a reinforcing steel plate.

Furthermore, the second structural beam and the reinforcing steel plate are connected through a split screw connecting piece.

The utility model provides a combined system is faced forever in assembly type building engineering fire control, the lower extreme of person in charge is connected with the total outlet pipe of ground in the building to make the fire-fighting water in the total outlet pipe directly enter along the person in charge, and the lower extreme of person in charge is directly connected with the total outlet pipe in the building, later stage need not dismantle, has practiced thrift fire extinguishing system material cost and artifical installation cost; the upper end of the main pipe is connected with the water inlet of the branch pipe, so that the fire-fighting water in the main pipe can enter along the water inlet of the branch pipe; the branch pipes penetrate through the first structural beam so as to limit the installation positions of the branch pipes by using the first structural beam, and the branch pipes directly penetrate through the building, so that the installation is convenient; the water outlet end of the branch pipe is connected with a fire hydrant, so that fire-fighting water can be supplied to the fire hydrant conveniently; the fire hydrant is connected on the bearing wall in the building, ensures that the mounted position of fire hydrant is firm, also is convenient for the later stage to fix a position according to the design requirement and adjusts. The utility model discloses an assembly type building engineering fire control faces combination system forever, owing to be direct mount in the building to only need the one-time installation, the later stage need not to dismantle the change, has saved the fire control cost, has still practiced thrift the installation cost.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a front view of a fire fighting permanent temporary combined system for assembly type building engineering provided by an embodiment of the present invention;

fig. 2 is a top view of the assembled building engineering fire fighting permanent temporary joint system provided by the embodiment of the present invention;

fig. 3 is a schematic perspective view of a fire fighting permanent facing combined system in an assembly type building engineering provided by the embodiment of the present invention.

Icon:

100-main tube; 200-branch pipe; 300-fire hydrant; 400-a first structural beam; 500-load bearing walls; 600-a second structural beam;

401-a limiting hole; 402-a position limiting sleeve;

601-reinforcing battens; 602-raised end of wood square; 603-reinforcing steel plates; 604-opposite pulling screw connection.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 to 3, the utility model provides an assembled building engineering fire fighting permanent temporary combined system, which comprises a main pipe 100, a branch pipe 200, a fire hydrant 300, a first structural beam 400 and a prefabricated laminated slab;

be responsible for 100's lower extreme and the total water piping connection of ground in the building, be responsible for 100's upper end and pass prefabricated superimposed sheet and rise to the working face, be responsible for 100 and can pass prefabricated superimposed sheet's reservation entrance to a cave, prefabricated superimposed sheet reservation entrance to a cave needs pinpoint, and during the installation superimposed sheet, need pinpoint, it is downthehole to ensure that fire control is responsible for 100 and passes smoothly.

The branch pipe 200 is inserted into a first structural beam 400 in a building, the water outlet end of the branch pipe 200 is connected with a fire hydrant 300, and the fire hydrant 300 is connected on a bearing wall 500 in the building.

In fig. 3, the lower end of the main pipe 100 is connected to the ground in the building through a fixing bracket, and the lower end of the main pipe 100 is connected and fixed to the main outlet pipe of the ground to ensure that the fire fighting water in the outlet pipe can enter along the lower end of the main pipe 100.

The upper end of the main pipe 100 is vertically connected to the water inlet at the right end of the branch pipe 200 so that the fire extinguishing water in the main pipe 100 can enter along the water inlet at the right end of the branch pipe 200.

The branch pipe 200 is inserted into the first structural beam 400 at the top of the building, and the first structural beam 400 is used to support and fix the installation position of the branch pipe 200.

The water outlet end of the lower end of the branch pipe 200 is connected to the hydrant 300 so that the fire-fighting water in the branch pipe 200 can be used by the hydrant 300.

The fire hydrant 300 is connected to the side surface of the bearing wall 500 in the building through bolts, and after the building is built, the position of the fire hydrant 300 is shifted according to the design requirement, so that the design position requirement is met.

The lower end of the main pipe 100 of the utility model is directly connected with the total water outlet pipe of the ground in the building, the upper end of the main pipe 100 is connected with the fire hydrant 300 through the branch pipe 200, the branch pipe 200 is arranged in the first structural beam 400 in the building in a penetrating way, and the fire hydrant 300 is connected on the bearing wall 500 in the building; the main pipe 100, the branch pipe 200 and the fire hydrant 300 are all connected in the building, compared with the prior art, the utility model avoids the secondary installation of a fire-fighting system, saves the investment cost of fire-fighting materials for the whole construction project and saves the cost; directly install the fire-fighting equipment to the working face, need not artifical secondary installation, both satisfied the interim fire water requirement of building engineering, also practiced thrift the artifical expense of installing of later stage formal fire control.

Further, the main pipe 100 is raised to the working surface through the reserved hole of the laminated slab, the first structural beam 400 is provided with a limiting hole 401, and the branch pipe 200 is arranged in the limiting hole 401 in a penetrating manner.

As shown in fig. 3, in an embodiment of the present invention, on the first structural beam 400, a limiting hole 401 is disposed along the thickness direction of the first structural beam 400, the limiting hole 401 is a circular through hole, and the branch pipe 200 is inserted into the circular through hole, so as to support and fix the position of the branch pipe 200 by using the circular through hole.

The utility model discloses a further embodiment, on first structure roof beam 400, set up spacing hole 401 along the thickness direction of first structure roof beam 400, spacing hole 401 is oval through-hole, and the major axis direction of oval through-hole is the same with the width direction of first structure roof beam 400 to when making branch pipe 200 put into oval through-hole, branch pipe 200 leans on the position reservation that the oval through-hole leans on has certain clearance, the installation of branch pipe 200 in vertical direction position of being convenient for.

In other embodiments of the present invention, the limiting hole 401 may be a square through hole, an irregular through hole, or the like, as long as the branch pipe 200 can be conveniently fixed.

Furthermore, a limiting sleeve 402 is connected in the limiting hole 401, and the branch pipe 200 is arranged in the limiting sleeve 402 in a penetrating manner.

As shown in fig. 1, a limiting sleeve 402 is connected in the limiting hole 401 to ensure that the installation position of the branch pipe 200 is firm and the branch pipe 200 does not break away from the limiting hole 401; the use of the stop collar 402 also facilitates locating the installation location of the branch pipe 200 along the thickness direction of the first structural beam 400.

Further, the diameter of the stopper hole 401 is larger than that of the branch pipe 200.

As shown in fig. 3, the diameter of the limiting hole 401 is larger than that of the branch pipe 200, so that a certain gap is left in the upper position of the branch pipe 200 in the limiting hole 401, and the branch pipe 200 is ensured to be accurately installed and fixed.

Further, a reinforcing pad is connected in the limiting hole 401.

The utility model discloses an in the embodiment, the reinforcing pad adopts the rubber pad, adopts glue bonding rubber pad in spacing hole 401, then connects spacing sleeve 402 on the rubber pad again, increases the frictional force between spacing sleeve 402 and the spacing hole 401, avoids spacing sleeve 402 to remove along the length direction of spacing hole 401 inner peripheral surface to ensure that the mounted position of branch pipe 200 in the spacing sleeve 402 is accurate.

In other embodiments of the present invention, anti-skid lines may be added on the upper end surface of the rubber pad to further increase the friction force on the surface of the rubber pad;

or, the upper end surface of the rubber pad is increased with anti-skid convex particles;

or, an inwardly concave arc-shaped groove is formed in the upper end surface of the rubber pad, so that the branch pipe 200 is embedded in the arc-shaped groove and fixed.

Further, a second structural beam 600 is included;

the second structural beam 600 is connected to the terminal end of the first structural beam 400, and the second structural beam 600 is disposed at the side of the branch pipe 200.

In fig. 3, the terminating end of the inner side of the first structural beam 400 is perpendicularly connected to the inner side of the second structural beam 600, and the second structural beam 600 is disposed at the inner side of the branch pipe 200 such that the length direction of the second structural beam 600 is parallel to the length direction of the branch pipe 200, and the second structural beam 600 is used as a reference to ensure the accurate installation position of the branch pipe 200.

Further, a reinforcing batten 601 is connected to the end surface of the inner side of the second structural beam 600 far away from the branch pipe 200.

As shown in fig. 2, a reinforcing batten 601 is connected to a position on the inner side end surface of the second structural beam 600 near the right side to fix the position of the inner side end surface of the second structural beam 600; meanwhile, since the length direction of the branch pipe 200 is arranged in parallel to the length direction of the second structural beam 600, the right end installation position of the branch pipe 200 can also be positioned by using the reinforcing flitch 601.

Further, the outer side end face of the reinforcing batten 601 is provided with a batten protruding end 602.

In fig. 2, at the outer end surface of the reinforcing batten 601, namely: in fig. 2, a raised end 602 is provided at the right position, and the raised end 602 abuts against and fixes the position of the reinforcing batten 601.

Further, a reinforcing steel plate 603 is attached to the inner end surface of the second structural beam 600 near the branch pipe 200.

In fig. 2, since the reinforcing batten 601 is provided with the batten protruding end 602, in order to prevent the batten protruding end 602 from abutting against the branch pipe 200, the reinforcing steel plate 603 is connected to the inner end surface of the second structural beam 600.

The medial surface of reinforcing steel plate 603 connects the medial surface of second structural beam 600, and the lateral surface of reinforcing steel plate 603 sets up with the medial surface of branch pipe 200 end face parallel, because the lateral surface of reinforcing steel plate 603 is planar structure, can not cause the butt conflict to branch pipe 200, can also protect the position of branch pipe 200.

Further, the second structural beam 600 and the reinforcing steel plate 603 are connected through a split screw connector 604.

In the reinforcing process of the beam template, the beam template can conflict with the position of the fire fighting pipe, so that the reinforcing steel plate 603 is changed for reinforcing, the reinforcing space is reduced, and the reinforcing space is not influenced.

In an embodiment of the present invention, the tie rod connecting member 604 is a tie rod screw, which is provided with two connecting holes on the second structural beam 600 and the reinforcing steel plate 603, the middle rod of the tie rod sequentially passes through the two connecting holes, and the two ends of the tie rod are both provided with a horizontally disposed butt rod, so as to utilize the two butt rods to respectively butt against the outer side surfaces of the second structural beam 600 and the reinforcing steel plate 603, thereby ensuring that the connecting position between the second structural beam 600 and the reinforcing steel plate 603 is firm.

In addition, in order to ensure that the connection position of the reinforcing steel plate 603 is firm, a strip-shaped groove can be further arranged on the outer side surface of the reinforcing steel plate 603, a connection through hole is arranged in the middle of the strip-shaped groove, and the length value and the width value of the strip-shaped groove are respectively the same as the length value and the width value of the abutting rod so as to limit the position of the abutting rod by utilizing the strip-shaped groove.

In other embodiments of the present invention, the tie rod connector 604 may also adopt bolts to connect the second structural beam 600 and the reinforcing steel plate 603.

The utility model provides an assembly type building engineering fire control faces binding system forever, during the installation, install the beam template of first structure roof beam 400 earlier, ligature roof beam reinforcing bar, then install the beam template of second structure roof beam 600, ligature roof beam reinforcing bar, the medial extremity face at second structure roof beam 600 is connected to reinforcement steel sheet 603, be close to inboard position, utilize and connect second structure roof beam 600 to drawing screw rod connecting piece 604, reinforcement steel sheet 603, the medial extremity face at second structure roof beam 600 is connected to reinforcement flitch 601, be close to the position in the outside, it is fixed to reinforcing flitch 601 locking to utilize flitch protruding end 602. And finally, the holes reserved in advance through the laminated slab are lifted to an operation layer, and the holes are reserved at the position of the fire-fighting main pipe 100 before the PC laminated slab is prefabricated, so that the installation condition is provided for later installation.

The utility model connects the lower end of the main pipe 100 with the total water outlet pipe of the ground in the building, the upper end of the main pipe 100 is vertically connected with the water inlet of the branch pipe 200, the branch pipe 200 is arranged in the limit sleeve 402 in a penetrating way, the water outlet end of the branch pipe 200 is connected with the fire hydrant 300, and the fire hydrant 300 is fixed on the bearing wall 500 in the building by bolts; after the installation is finished, the two structural beams are poured and fixed, the templates are respectively disassembled, and the fire hydrant 300 is installed after the bearing wall templates are disassembled.

The utility model discloses a fire extinguishing system direct mount is under construction in the building together with the building to an installation is compared with prior art, has saved the fire control tubular product expense of fire control facility greatly, simultaneously, has also saved operation personnel's installation expense.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. An assembled fire fighting permanent temporary combination system for building engineering is characterized by comprising a main pipe (100), branch pipes (200), fire hydrants (300), a first structural beam (400) and prefabricated laminated slabs;

the lower end of the main pipe (100) is connected with a total water outlet pipe on the ground in the building, the upper end of the main pipe (100) penetrates through the prefabricated laminated slab to rise to the working surface, the main pipe (100) can penetrate through a reserved hole of the prefabricated laminated slab,

the branch pipe (200) is arranged in the first structural beam (400) in the building in a penetrating mode, the water outlet end of the branch pipe (200) is connected with the fire hydrant (300), and the fire hydrant (300) is connected to a bearing wall (500) in the building.

2. Assembled construction fire fighting permanent temporary joint system according to claim 1, characterized in that the first structural beam (400) is provided with a limiting hole (401), the branch pipe (200) being arranged through the limiting hole (401).

3. The fabricated building engineering fire fighting permanent temporary bonding system of claim 2, wherein a limiting sleeve (402) is connected in the limiting hole (401), and the branch pipe (200) is arranged in the limiting sleeve (402) in a penetrating manner.

4. Assembled building engineering fire fighting permanent temporary bonding system according to claim 2, characterized in that the diameter of the limiting hole (401) is larger than the diameter of the branch pipe (200).

5. The prefabricated construction fire fighting permanent temporary bonding system of claim 2, wherein a reinforcing pad is connected in the limiting hole (401).

6. The fitted building engineering fire fighting permanent temporary joint system according to claim 1, further comprising a second structural beam (600);

the second structural beam (600) is connected to the terminating end of the first structural beam (400), the second structural beam (600) being disposed laterally of the branch pipe (200).

7. Fabricated construction-work fire-fighting permanent temporary bonding system according to claim 6, characterized in that a reinforcing batten (601) is connected to the inner end face of the second structural beam (600) away from the branch pipe (200).

8. The fabricated building engineering fire fighting permanent temporary bonding system of claim 7, wherein the outer side end face of the reinforcing battens (601) is provided with battens protruding ends (602).

9. The prefabricated construction fire fighting permanent temporary bonding system of claim 7, wherein a reinforcing steel plate (603) is connected to the second structural beam (600) near the inboard end face of the branch pipe (200).

10. The fabricated building engineering fire fighting permanent temporary bonding system of claim 9, wherein the second structural beam (600) and the reinforcing steel plate (603) are connected by a split screw connector (604).

Images