CN216810344U - Be applied to civil engineering's building roofing movement joint seepage prevention structure - Google Patents

Abstract

The utility model provides a leakage-proof structure applied to a deformation joint of a building roof in civil engineering. Be applied to civil engineering's building roof movement joint leak-proof structure includes: grooves formed in the tops of the two walls; the two fixing rods are fixedly arranged in the two grooves respectively; the rubber water stop is arranged between the two walls; the two sliding plates are respectively installed on the two fixed rods in a sliding manner; the two adjusting grooves are respectively arranged at the tops of the two sliding plates. The building roof deformation joint leakage-proof structure applied to civil engineering provided by the utility model has the advantages of convenience in use, simplicity in operation and capability of enabling the water stop belt to be tightly attached to the wall all the time.

Description

Be applied to civil engineering's building roofing movement joint seepage prevention structure

Technical Field

The utility model relates to the technical field of civil engineering, in particular to a leakage-proof structure applied to a deformation joint of a building roof in civil engineering.

Background

The deformation joint is a general name of an expansion joint, a settlement joint and a shockproof joint. The building is often deformed by external factors, resulting in cracking and even destruction. The deformation joint is a reserved structural joint for the situation, the leakage of the roof deformation joint is one of the most prominent common quality problems of house buildings for many years, the leakage prevention structure seriously affects the use function of the buildings and the overall quality of engineering, and in order to prevent external rainwater from entering the deformation joint, people generally fixedly install leakage prevention structures on two walls.

However, the existing joint leakage-proof structure is generally fixedly installed at the tops of two building roofs through a plurality of connecting bolts, but the phenomenon of looseness can occur when the fixing bolts are used for a period of time, so that the joint leakage-proof structure cannot be tightly attached to the building roofs, and rainwater enters into deformation joints.

Therefore, there is a need for a new leakage-proof structure for deformation joints of building roofs applied to civil engineering to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide the anti-seepage structure for the deformation joint of the building roof, which is convenient to use, simple to operate and applied to civil engineering and enables the water stop belt to be always tightly attached to the wall.

In order to solve the technical problem, the anti-seepage structure applied to the deformation joint of the building roof in civil engineering provided by the utility model comprises: grooves formed in the tops of the two walls; the two fixing rods are fixedly arranged in the two grooves respectively; the rubber water stop is arranged between the two walls; the two sliding plates are respectively installed on the two fixed rods in a sliding manner; the two adjusting grooves are respectively formed in the tops of the two sliding plates; the two connecting plates are respectively and slidably arranged in the two adjusting grooves; the two compression springs are fixedly arranged in the two adjusting grooves respectively; the two connecting rods are rotatably arranged at the tops of the two connecting plates respectively, and the top ends of the two connecting rods extend to the outside of the corresponding adjusting grooves respectively.

Preferably, the two joint rods are respectively provided with a long plate in a sliding manner, the two joint rods penetrate through the long plates, and the top ends of the two joint rods are respectively and fixedly provided with a pressing plate.

Preferably, pull rings are fixedly mounted at the tops of the two pressing plates respectively, water draining grooves are fixedly mounted in the two adjusting grooves respectively, the two water draining grooves are communicated with the corresponding adjusting grooves respectively, through holes are formed in the long plate, and the two connecting rods penetrate through the corresponding through holes and are movably connected with the corresponding through holes.

Preferably, the top fixed mounting of rubber waterstop has two fixed plates, two the standing groove has been seted up respectively at the top of fixed plate, the bottom fixed mounting of long slab has two mounting panels, and two the bottom of mounting panel extends to corresponding respectively in the standing groove, two the draw-in groove has been seted up respectively on the one side outer wall that the mounting panel was kept away from each other, two on the one side outer wall that the fixed plate was kept away from each other respectively slidable mounting has the cardboard, and two one side that the cardboard is close to each other extends to corresponding respectively in the draw-in groove.

Preferably, the outer wall of one side, far away from each other, of each of the two clamping plates is fixedly provided with a movable plate, the two clamping plates are movably sleeved with stressed springs respectively, the ends, close to each other, of the two stressed springs are fixedly connected with the corresponding fixed plates respectively, and the ends, far away from each other, of the two stressed springs are fixedly connected with the corresponding movable plates respectively.

Preferably, through holes are respectively formed in the two sliding plates, linear bearings are respectively and fixedly mounted in the two through holes, and the two fixing rods respectively penetrate through the corresponding linear bearings and are in sliding connection with the inner walls of the corresponding linear bearings.

Preferably, the inner walls of two sides of the two adjusting grooves are respectively provided with a limiting groove, and two sides of the two connecting plates respectively extend into the corresponding limiting grooves and are in sliding connection with the inner walls of the corresponding limiting grooves.

Compared with the prior art, the anti-seepage structure applied to the deformation joint of the building roof in civil engineering has the following beneficial effects:

the utility model provides a leakage-proof structure for deformation joints of building roofs, which is applied to civil engineering and prevents rainwater from entering the deformation joints through a rubber water stop belt, the pressing plate is always pressed by a downward pulling force under the action of the compression spring to extrude the long plate, so that the fixing plate extrudes the rubber water stop, the rubber water stop is always tightly attached to the top of the building roof, rainwater is prevented from entering a deformation joint through a gap between the rubber water stop and the building roof, the pressing plate is driven to rotate through the rotation of the pull ring, make the clamp plate enter into the opening under compression spring's effect in, drive the cardboard through the removal movable plate and leave the draw-in groove, upwards remove the long slab and dismantle from the sliding plate and get off and show the rubber waterstop out, people upwards remove the fixed plate again and can dismantle the rubber waterstop from the building roofing get off, the process is simple quick, work efficiency is high.

Drawings

FIG. 1 is a schematic structural view of a preferred embodiment of the leakage-preventing structure for deformation joints of building roofs applied to civil engineering, according to the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is an enlarged view of the portion B shown in FIG. 1;

fig. 4 is a partial plan view of the elongated plate shown in fig. 1.

Reference numbers in the figures: 1. a groove; 2. fixing the rod; 3. a sliding plate; 4. an adjustment groove; 5. a compression spring; 6. a connector tile; 7. a connecting rod; 8. a long plate; 9. pressing a plate; 10. a pull ring; 11. a rubber waterstop; 12. a fixing plate; 13. mounting a plate; 14. a card slot; 15. clamping a plate; 16. moving the plate; 17. a stressed spring.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

Referring to fig. 1-4, fig. 1 is a schematic structural view of a preferred embodiment of an anti-seepage structure for deformation joints of building roofs applied to civil engineering, according to the present invention; FIG. 2 is an enlarged view of the portion A shown in FIG. 1; FIG. 3 is an enlarged view of the portion B shown in FIG. 1; fig. 4 is a partial plan view of the elongated plate shown in fig. 1. Be applied to civil engineering's building roofing movement joint seepage prevention structure includes: the groove 1 is formed in the tops of the two walls; the two fixing rods 2 are respectively and fixedly arranged in the two grooves 1; the rubber water stop belt 11 is arranged between the two walls, and rainwater is prevented from entering the deformation joint through the rubber water stop belt 11; the two sliding plates 3 are respectively and slidably mounted on the two fixed rods 2; the two adjusting grooves 4 are respectively formed in the tops of the two sliding plates 3; two connecting plates 6, wherein the two connecting plates 6 are respectively and slidably arranged in the two adjusting grooves 4; the two compression springs 5 are fixedly arranged in the two adjusting grooves 4 respectively, the lower pressing plate 9 is always subjected to downward pulling force to extrude the lower long plate 8 under the action of the compression springs 5, the long plate 8 extrudes the fixed plate 12, the fixed plate 12 extrudes the rubber water stop band 11, the rubber water stop band 11 is always tightly attached to the top of a building roof, and rainwater is prevented from entering a deformation joint through the rubber water stop band 11; two link rods 7, two link rods 7 rotate respectively and install two the top of linking up fishplate bar 6, and two the top of linking up fishplate bar 7 extends respectively to corresponding outside the adjustment tank 4, two link rods 7 rotate through two connecting bearing and install on two linking up fishplate bar 6, rotate through linking up and install on linking up fishplate bar 6, make people when rotating on linking up fishplate bar 7 do not cause the influence to linking up fishplate bar 6.

In order to extrude the long plate 8 and further enable the rubber water stop band 11 to be tightly attached to the building roof all the time, the long plate 8 is slidably mounted on the connecting rods 7 respectively, the two connecting rods 7 penetrate through the long plate 8, and the top ends of the two connecting rods 7 are fixedly provided with pressing plates 9 respectively.

In order to make people's more convenient removal clamp plate 9, two there is pull ring 10, two at the top of clamp plate 9 fixed mounting respectively there is the sluicing groove, and two in the adjustment tank 4 respectively fixed mounting have the sluicing groove, and two the sluicing groove respectively with corresponding adjustment tank 4 communicates with each other, the opening has been seted up on the long slab 8, two it is corresponding that linking rod 7 runs through respectively the opening and with corresponding opening swing joint discharges away the external rainwater that will enter into in the adjustment tank 4 through the sluicing groove, prevents that compression spring 5 from soaking in the rainwater for a long time, influences compression spring 5's life.

In order to clamp the mounting plate 13, and then fix the mounting plate 13 on the fixing plate 12, the top of the rubber water stop 11 is fixedly provided with two fixing plates 12, two placing grooves are respectively formed in the top of the fixing plates 12, two mounting plates 13 are fixedly provided in the bottom of the long plate 8, and two bottoms of the mounting plates 13 respectively extend to be corresponding to the placing grooves, two clamping grooves 14 and two clamping plates 15 are respectively formed in the outer wall of one side, away from each other, of the mounting plates 13, the outer wall of one side, away from each other, of the fixing plates 12 is respectively provided with a clamping plate 15, one side, close to each other, of the clamping plates 15 respectively extends to be corresponding to the clamping grooves 14, one side, located through the clamping plates 15, clamps the mounting plate 13 in the clamping grooves 14, and then fix the mounting plate 13 on the fixing plate 12.

In order to enable the clamping plates 15 to be located in the clamping grooves 14 all the time to clamp the mounting plate 13 without being affected by external force, the outer walls of the two clamping plates 15 at the sides far away from each other are respectively and fixedly provided with a moving plate 16, the two clamping plates 15 are respectively and movably sleeved with stress springs 17, the ends, close to each other, of the two stress springs 17 are respectively and fixedly connected with the corresponding fixed plates 12, and the ends, far away from each other, of the two stress springs 17 are respectively and fixedly connected with the corresponding moving plates 16.

In order to reduce the friction force between the fixing rods 2 and the sliding plates 3 and further reduce the abrasion degree of the fixing rods 2 and prolong the service life of the fixing rods 2, through holes are respectively formed in the two sliding plates 3, linear bearings are respectively and fixedly mounted in the two through holes, and the two fixing rods 2 respectively penetrate through the corresponding linear bearings and are in sliding connection with the inner walls of the corresponding linear bearings.

In order to limit the connecting plates 6 and prevent the connecting rods 7 from influencing the connecting plates 6 when rotating, limiting grooves are respectively formed in the inner walls of two sides of the two adjusting grooves 4, and two sides of the two connecting plates 6 respectively extend into the corresponding limiting grooves and are in sliding connection with the inner walls of the corresponding limiting grooves.

The working principle of the anti-seepage structure applied to the deformation joint of the building roof in civil engineering provided by the utility model is as follows: the compression spring 5 is in a stretching state in an initial state, the stress spring 17 is in a free state, the pressing plate 9 is always pressed by a downward pulling force to extrude the long plate 8 under the action of the compression spring 5, the long plate 8 is further extruded to the fixing plate 12, the rubber water stop band 11 is extruded through the fixing plate 12 to be tightly attached to the top of a building roof all the time, the rubber water stop band 11 prevents rainwater from entering a deformation joint, one side of the clamping plate 15 of the stress spring 17 is always positioned in the clamping groove 14 to clamp the mounting plate 13, the long plate 8 is further fixedly mounted on the fixing plate 12, when the rubber water stop band 11 needs to be disassembled, the pull ring 10 is moved, the pull ring 10 moves to drive the pressing plate 9 to be separated from the long plate 8, when the pressing plate 9 is completely separated from the long plate 8, the pull ring 10 is rotated to drive the pressing plate 9 to rotate, the pressing plate 9 enters the through opening under the action of the compression spring 5, when the pressing plate 9 completely enters the through hole, the movable moving plate 16 drives the clamping plate 15 to leave the clamping groove 14, when the clamping plate 15 completely leaves the clamping groove 14, the upward moving movable long plate 8 is detached from the sliding plate 3 to display the rubber water stop 11, and then the upward moving fixed plate 12 can detach the rubber water stop 11 from the building roof, so that the process is simple and quick, and the working efficiency is high.

Compared with the prior art, the anti-seepage structure applied to the deformation joint of the building roof in civil engineering has the following beneficial effects:

the utility model provides a leakage-proof structure for a deformation joint of a building roof, which is applied to civil engineering.A rubber water stop 11 is used for preventing rainwater from entering the deformation joint, a pressing plate 9 is always pressed by a downward pulling force to extrude a long plate 8 under the action of a compression spring 5, a fixing plate 12 is further used for pressing the rubber water stop 11, the rubber water stop 11 is always tightly attached to the top of the building roof, the rainwater is prevented from entering the deformation joint through a gap between the rubber water stop 11 and the building roof, the pressing plate 9 is driven to rotate through rotation of a pull ring 10, the pressing plate 9 enters a through opening under the action of the compression spring 5, a moving plate 16 is used for driving a clamping plate 15 to leave a clamping groove 14, the moving long plate 8 is moved upwards to detach the rubber water stop 11 from the sliding plate 3, and then the fixing plate 12 is moved upwards to detach the rubber water stop 11 from the building roof, the process is simple and quick, and the work efficiency is high.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (7)

1. The utility model provides a be applied to civil engineering's building roof movement joint anti-seepage leak structure which characterized in that includes:

grooves formed in the tops of the two wall bodies;

the two fixing rods are respectively and fixedly arranged in the two grooves;

the rubber water stop is arranged between the two walls;

the two sliding plates are respectively installed on the two fixed rods in a sliding manner;

the two adjusting grooves are respectively formed in the tops of the two sliding plates;

the two connecting plates are respectively and slidably arranged in the two adjusting grooves;

the two compression springs are fixedly arranged in the two adjusting grooves respectively;

the two connecting rods are rotatably arranged at the tops of the two connecting plates respectively, and the top ends of the two connecting rods extend to the outside of the corresponding adjusting grooves respectively.

2. The structure of claim 1, wherein the two connecting rods are slidably provided with long plates respectively, penetrate through the long plates and are fixedly provided with pressing plates at the top ends respectively.

3. The structure of claim 2, wherein the top of each of the two pressing plates is fixedly provided with a pull ring, the top of each of the two adjusting grooves is fixedly provided with a drainage groove, the two drainage grooves are respectively communicated with the corresponding adjusting grooves, the long plate is provided with through holes, and the two connecting rods respectively penetrate through and are movably connected with the corresponding through holes.

4. The building roof deformation joint leakage prevention structure applied to civil engineering as claimed in claim 3, wherein two fixing plates are fixedly mounted on the top of the rubber water stop, a placing groove is respectively formed on the top of each fixing plate, two mounting plates are fixedly mounted on the bottom of the long plate, the bottom of each mounting plate extends into the corresponding placing groove, a clamping groove is respectively formed on the outer wall of one side of each mounting plate away from the other mounting plate, a clamping plate is respectively slidably mounted on the outer wall of one side of each fixing plate away from the other mounting plate, and the side of each clamping plate close to the other mounting plate extends into the corresponding clamping groove.

5. The structure of claim 4, wherein the outer walls of the two clamping plates at the sides away from each other are respectively fixedly provided with a moving plate, the two clamping plates are respectively movably sleeved with a force-bearing spring, the ends of the two force-bearing springs close to each other are respectively fixedly connected with the corresponding fixed plates, and the ends of the two force-bearing springs far from each other are respectively fixedly connected with the corresponding moving plates.

6. The structure of claim 5, wherein the two sliding plates are respectively provided with a through hole, a linear bearing is fixedly installed in each through hole, and the two fixing rods respectively penetrate through the corresponding linear bearing and are slidably connected with the inner wall of the corresponding linear bearing.

7. The building roof deformation joint leakage prevention structure applied to civil engineering as claimed in claim 5, wherein two inner walls of the two adjusting grooves are respectively provided with a limiting groove, and two sides of the two connecting plates respectively extend into the corresponding limiting grooves and are slidably connected with the inner walls of the corresponding limiting grooves.

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