CN220100680U - Diagonal bracing device of aluminum template - Google Patents

Abstract

The utility model relates to the technical field of building construction, in particular to an inclined strut device of an aluminum template, which comprises an embedded support, wherein a mounting support is movably arranged on the embedded support, a first adjusting component for adjusting the transverse position is arranged between the mounting support and the embedded support, a hinged support is arranged on the mounting support, a second adjusting component for adjusting the longitudinal position is arranged between the hinged support and the mounting support, and an inclined strut is arranged on the hinged support. According to the utility model, by arranging the embedded support embedded in the floor concrete to be matched with the mounting support, when the diagonal bracing support is mounted on the ground, the ground concrete collar is not damaged, and the quality of the floor concrete is ensured; through setting up first adjusting part and second adjusting part, carry out horizontal and vertical position control to mount pad and free bearing respectively, the bracing support has installed the flexibility.

Description

Diagonal bracing device of aluminum template

Technical Field

The utility model relates to the technical field of building construction, in particular to an inclined strut device of an aluminum template.

Background

The aluminum mould is widely applied to concrete pouring because of the characteristics of high assembly efficiency, good finished product impression, repeated utilization and the like, wherein pouring of a wall body is required to be provided with a diagonal bracing for supporting the aluminum mould to resist pouring pressure besides the wall body mould, one end of the diagonal bracing supports the aluminum mould, and the other end of the diagonal bracing is abutted against the ground to provide counter force for the aluminum mould.

At present, most of diagonal braces are hinged with the ground by adopting existing supports, the supports have higher installation flexibility, holes are drilled on the ground at determined positions, and fixing can be realized by using expansion bolts for installation, but the defects are obvious, and the supports are not suitable for the ground with high waterproof requirements and the ground embedded with hydropower pipelines. Some diagonal braces are installed by adopting an embedded part to be matched with the existing support, but the flexibility of installation is correspondingly lost, and certain trouble is brought to diagonal brace adjustment.

Disclosure of Invention

In order to ensure that the installation of the diagonal brace does not need to damage the ground, the concrete finished product is protected, and the installation flexibility is realized, the utility model provides the diagonal brace device of the aluminum template.

The utility model provides an inclined strut device of an aluminum template, which adopts the following technical scheme:

the utility model provides an aluminum template's bracing device, includes pre-buried support, pre-buried support is last to be movably to be provided with on the support, the support with be provided with between the pre-buried support and be used for adjusting transverse position's first adjusting part, be provided with the free bearing on the support, the free bearing with be provided with between the support and be used for adjusting longitudinal position's second adjusting part, be provided with the diagonal brace on the free bearing.

By adopting the technical scheme, the inclined strut is installed without damaging the ground, and the design purpose of installation flexibility is achieved. Specifically, the present utility model relates to a method for manufacturing a semiconductor device. The installation range of the diagonal bracing support of the next layer is determined before the bottom plate concrete is poured, the embedded support is installed, after the aluminum die is installed, the installation support is installed on the embedded support, and then the positions of the installation support and the hinged support are adjusted through the first adjusting component and the second adjusting component according to the requirement, so that the installation flexibility is realized.

Optionally, the first adjusting part includes first slide, first spout has been seted up on the pre-buried support, first slide slides and sets up in the first spout, be provided with first draw-in groove in the first spout, be provided with first draw-in hole on the first slide, first draw-in hole slides and is provided with first card post, first card post is provided with the pulling piece.

By adopting the technical scheme, the first sliding seat is locked. Specifically, when the first sliding seat is adjusted to a required position, the first clamping column is put down, and the first clamping column is clamped into the first clamping groove, so that the first sliding seat is locked. When the unlocking is needed, the first clamping column is lifted through the lifting piece, and the first clamping column exits the first clamping groove, so that the unlocking is realized.

Optionally, first adjusting part includes the second slide, the second spout has been seted up on the pre-buried support, the second slide slides and sets up in the second spout, the second slide is provided with the connecting hole, be provided with the second card hole on the second slide, second card hole intercommunication the connecting hole, be provided with the second card post in the second card hole, be provided with the spring in the second card hole, the one end of second card post sets up to the inclined plane and stretches into the connecting hole, the connecting hole is provided with the connecting rod in the slip, be provided with the second draw-in groove in the second spout.

Through adopting above-mentioned technical scheme, realized the locking of second slide, specifically, the connecting rod pushes down and on the inclined plane of butt second card post, the inclined plane converts vertical pressure into horizontal thrust, and second card post outwards extends and the joint second draw-in groove realizes the locking of second slide, and the spring pressurized stores elastic potential energy this moment. When the unlocking is needed, the connecting rod moves upwards and passes through the second clamping column, the spring releases elastic potential energy to push the second clamping column to move towards the direction of the connecting hole, and the second clamping column exits from the second clamping groove, so that unlocking is realized.

Optionally, one side of pre-buried support is provided with the thrust plate, the outside of thrust plate is provided with the reinforcing bar, the reinforcing bar is the heliciform setting.

Through adopting above-mentioned technical scheme, the thrust plate can make the pouring pressure to the wall body when pouring effectively spread to the floor concrete through the diagonal brace on, avoids compressive stress to exceed the compressive strength of concrete as far as possible, leads to the broken condition of concrete floor, guarantees the stability of aluminum mould board when the wall body is pour. The spiral reinforcing steel bars are arranged to strengthen the adhesion of the floor concrete, so that the end parts of the embedded support are prevented from being damaged by local concrete.

Optionally, the embedded support is further provided with a reinforcing rib, and two ends of the reinforcing rib are respectively connected with the embedded support and the thrust plate.

Through adopting above-mentioned technical scheme, the pressure dispersion that receives pre-buried support passes through the stiffening rib and transmits thrust plate department, avoids stress concentration in the junction of pre-buried support and thrust plate, the condition that the thrust plate can not play corresponding dispersion effect.

Optionally, the embedded support is further provided with a pull-out resistant steel bar, and the pull-out resistant steel bar faces downwards.

Through adopting above-mentioned technical scheme, strengthened the consolidation effect of pre-buried support and concrete floor, realized, avoided pre-buried support to take place to press as far as possible and rotate, the one end perk that pre-buried support is close to wall body aluminum mould, the condition that can't play the supporting role then takes place.

Optionally, the diagonal brace comprises an adjusting sleeve, and screw rods are connected to two ends of the adjusting sleeve in a threaded manner.

By adopting the technical scheme, the stretching lengths of the screw rods at the two ends are adjusted through the rotation of the adjusting pipe sleeve, so that the pre-pressure of the inclined strut on the aluminum mould is adjusted, and the support is provided for the wall aluminum mould.

Optionally, the adjusting sleeve is provided with an adjusting handle.

Through adopting above-mentioned technical scheme, utilize lever principle, increased and adjusted sheathed tube turning force arm, the workman is when adjusting the flexible volume of the same lead screw, and the force that needs is littleer, has saved workman's physical demands, improves workman's work efficiency.

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

1. through setting up the mode of pre-buried support cooperation erection support in the pre-buried floor concrete, realize when the bracing support is installed subaerial, do not destroy ground concrete collar, guarantee floor concrete quality.

2. Through setting up first adjusting part and second adjusting part, carry out horizontal and vertical position control to mount pad and free bearing respectively, the bracing support has installed the flexibility.

Drawings

FIG. 1 is a schematic overall structure of a first embodiment of the present utility model;

FIG. 2 is a schematic side sectional view of a first embodiment of the present utility model;

FIG. 3 is an enlarged detail view of portion A of FIG. 2;

FIG. 4 is a schematic overall structure of a second embodiment of the present utility model;

FIG. 5 is a schematic side sectional view of a second embodiment of the present utility model;

fig. 6 is an enlarged detail view of the portion B in fig. 5.

Reference numerals illustrate: 1. embedding a support; 11. a thrust plate; 12. reinforcing ribs; 13. reinforcing steel bars; 14. pulling-resistant steel bars; 2. a first adjustment assembly; 21. a first slider; 211. a first clamping hole; 212. a first clamping column; 22. a first chute; 221. a first clamping groove; 23. a second slider; 231. a second clamping hole; 232. a second clamping column; 24. a second chute; 241. a second clamping groove; 25. a connection hole; 26. a connecting rod; 3. a mounting support; 4. a second adjustment assembly; 5. a hinged support; 6. a diagonal brace; 61. adjusting the sleeve; 62. adjusting the handle; 63. and a screw rod.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-6.

Embodiment one:

referring to fig. 1-3, an inclined strut device of an aluminum template comprises an embedded support 1, wherein a thrust plate 11 is fixedly connected to one end of the embedded support 1, a reinforcing rib 12 is connected to the connecting position of the thrust plate 11 and the embedded support 1, the reinforcing rib 12 is triangular, and waist edges of two sides of the triangular reinforcing rib 12 are respectively connected with the thrust plate 11 and the embedded support 1. Two reinforcing steel bars 13 are fixedly connected to the outer side of the thrust plate 11, and the reinforcing steel bars 13 are spirally arranged. The bottom fixedly connected with resistance to plucking reinforcing bar 14 of pre-buried support 1, resistance to plucking reinforcing bar 14 are located the opposite one side of thrust plate 11, and resistance to plucking reinforcing bar 14 is down, and the bottom of resistance to plucking reinforcing bar 14 sets up to the turning, and the turning outwards.

The embedded support 1 is arranged on the reinforcing mesh before the concrete bottom plate is poured, and the top surface of the embedded support 1 is level with the elevation of the concrete bottom plate. When the diagonal bracing device works, the contact area of the pre-buried support 1 for transmitting pressure is increased through the thrust plate 11, so that the compressive stress of the pressed concrete is reduced, the compressive stress is within the strength range of the concrete, and the concrete is prevented from being locally damaged as much as possible.

The reinforcing rib 12 is an important component for ensuring the thrust plate 11 to play a desired role, and the pressure of the embedded support 1 can be transmitted to the thrust plate 11 through the reinforcing rib 12, so that the stress concentration at the connecting position of the embedded support 1 and the thrust plate 11 is avoided as much as possible.

The reinforcing steel bar 13 is another member for ensuring that the concrete is not locally damaged, so that the bonding with the floor concrete is enhanced, and the spiral type concrete is used for replacing part of the concrete to bear pressure, so that the compressive capacity of the local concrete is enhanced.

The anti-pulling steel bar 14 is connected with the steel bar net during the installation of the embedded support 1, so that the connection effect of the embedded support 1 and the concrete bottom plate is enhanced, the condition that one end of the embedded support 1 is pressed and the other end is pulled during working is avoided, drawing damage occurs, and the inclined support device cannot continue to work.

Referring to fig. 1-3, a mounting support 3 is movably mounted on a pre-buried support 1, two sets of first adjusting assemblies 2 are mounted between the mounting support 3 and the pre-buried support 1, each set of first adjusting assemblies 2 comprises a first sliding seat 21, the first sliding seats 21 are in threaded connection with the mounting support 3, two first sliding grooves 22 are formed in the pre-buried support 1, the first sliding seats 21 are slidably mounted in the first sliding grooves 22 one by one, two first clamping holes 211 are formed in each first sliding seat 21, first clamping columns 212 are slidably mounted in the first clamping holes 211, lifting rings are mounted at the tops of the first clamping columns 212 to serve as lifting pieces, and seven first clamping grooves 221 are formed in equal distances between the bottoms of the first sliding grooves 22.

Referring to fig. 1 to 3, the mounting bracket 3 is provided with a hinge seat 5, a set of second adjusting assemblies 4 is installed between the hinge seat 5 and the mounting bracket 3, the parts and the part relationship of the second adjusting assemblies 4 are the same as those of the first adjusting assemblies 2, and are not described herein, the difference is that the first adjusting assemblies 2 adjust the transverse position of the mounting base plate, and the second adjusting assemblies 4 adjust the longitudinal position of the hinge seat 5.

Referring to fig. 1-3, the hinge support 5 is hinged with two diagonal braces 6, the diagonal braces 6 comprise an adjusting sleeve 61 and two adjusting handles 62, the two adjusting handles 62 are fixedly connected to the adjusting sleeve 61 and are in a middle-shaped mode with the adjusting sleeve 61, two ends of the adjusting sleeve 61 are provided with threads and are in threaded connection with screw rods 63, the threads at the two ends are opposite threads, the screw rods 63 at one end of the adjusting sleeve 61 are hinged with the hinge support 5, and the screw rods 63 at the other end are connected with fixing pieces for fixing back ribs.

The number of the diagonal braces 6 is set according to the requirement. The length of the inclined stay bar 6 can be adjusted by rotating the adjusting handle 62, so that the pre-pressure of the inclined stay bar 6 on the aluminum mould is adjusted, and the support is provided for the wall aluminum mould; the arrangement of the adjusting handle 62 increases the rotating force arm of the adjusting sleeve 61, reduces the adjusting rotating force and saves the physical consumption of workers.

The working principle of the first embodiment is as follows: the pre-buried support 1 is pre-installed on the reinforcing steel bar net after pouring, the installation support 3 provided with the hinged support 5 is installed on the pre-buried support 1, the positions of the installation support 3 and the hinged support 5 are respectively adjusted through the first adjusting component 2 and the second adjusting component 4, when the first adjusting component 2 is locked, the first sliding seat 21 is adjusted to a required position, the first clamping column 212 is put down, the first clamping column 212 is clamped into the first clamping groove 221, the locking of the first sliding seat 21 is achieved, the second adjusting component 4 is locked together with the first adjusting component 2, after the adjustment is completed, the hinged support 5 is positioned at a required position, the diagonal brace 6 is installed, one end of the diagonal brace 6 is hinged to the hinged support 5, the other end supports the back edge on the aluminum die, and then the extending length of the screw 63 is adjusted through the adjusting handle 62, so that the pre-pressing force of the support is adjusted.

Embodiment two:

the structure of the second embodiment is substantially the same as that of the first embodiment, except that the structure of the first adjusting assembly 2 is different:

referring to fig. 4-6, in this embodiment, two sets of second adjusting assemblies 4 are installed between the mounting support 3 and the pre-buried support 1, each set of second adjusting assemblies 4 includes a second sliding seat 23, two second sliding grooves 24 are formed in the pre-buried support 1, and each second sliding groove 24 is slidably provided with the second sliding seat 23. Two connecting holes 25 are vertically formed in each second sliding seat 23, two second clamping holes 231 are formed in the position of each connecting hole 25 in each second sliding seat 23, the second clamping holes 231 are horizontally formed and are communicated with the connecting holes 25, second clamping columns 232 are slidably mounted in the second clamping holes 231, springs are mounted in the second clamping holes 231, the two ends of each spring are respectively abutted against the hole walls of the second clamping holes 231 and the second clamping columns 232, one ends of each spring are inclined planes are arranged at one ends of the corresponding second clamping columns 232 and extend into the corresponding connecting holes 25, the mounting support 3 is in threaded connection with the corresponding second sliding seat 23 through the corresponding connecting holes 25, a connecting rod 26 with a screw serving as a threaded connection is screwed into each connecting hole 25, and second clamping grooves 241 are formed in the second sliding grooves 24.

Referring to fig. 4-6, in the present embodiment, the components and the component relationships of the second adjusting assembly 4 are the same as those of the first adjusting assembly 2, and are not described herein, but the difference is that the first adjusting assembly 2 adjusts the transverse position of the mounting base plate, and the second adjusting assembly 4 adjusts the longitudinal position of the hinge base 5.

The working principle of the second embodiment is substantially the same as that of the first embodiment, and the difference is that the locking process of the first adjusting assembly 2 and the second adjusting assembly 4 in the two embodiments is different, and the first adjusting assembly 2 is taken as an example for explanation:

during installation of the mounting support 3, the screw is in threaded connection with the second sliding seat 23 through the connecting hole 25, the screw is used as the connecting rod 26 to press down and abut against the inclined surface of the second clamping column 232, vertical pressure is converted into horizontal thrust by the inclined surface, and the second clamping column 232 extends outwards and is clamped into the second clamping groove 241, so that the second sliding seat 23 is locked.

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 (7)

1. The utility model provides an aluminium template's bracing device which characterized in that: the embedded support comprises an embedded support (1), wherein an installing support (3) is movably arranged on the embedded support (1), a first adjusting component (2) for adjusting the transverse position is arranged between the installing support (3) and the embedded support (1), a hinged support (5) is arranged on the installing support (3), a second adjusting component (4) for adjusting the longitudinal position is arranged between the hinged support (5) and the installing support (3), and an inclined strut (6) is arranged on the hinged support (5);

the first adjusting component (2) comprises a first sliding seat (21), a first sliding groove (22) is formed in the embedded support (1), the first sliding seat (21) is arranged in the first sliding groove (22) in a sliding mode, a first clamping groove (221) is formed in the first sliding groove (22), a first clamping hole (211) is formed in the first sliding seat (21), a first clamping column (212) is arranged in the first clamping hole (211) in a sliding mode, and a lifting piece is arranged on the first clamping column (212).

2. A diagonal bracing device for aluminium templates according to claim 1, wherein: the first adjusting component (2) comprises a second sliding seat (23), a second sliding groove (24) is formed in the embedded support (1), the second sliding seat (23) is arranged in the second sliding groove (24) in a sliding mode, a connecting hole (25) is formed in the second sliding seat (23), a second clamping hole (231) is formed in the second sliding seat (23), the second clamping hole (231) is communicated with the connecting hole (25), a second clamping column (232) is arranged in the second clamping hole (231), a spring is arranged in the second clamping hole (231), one end of the second clamping column (232) is arranged to be inclined and stretches into the connecting hole (25), a connecting rod (26) is arranged in the connecting hole (25) in a sliding mode, and a second clamping groove (241) is formed in the second sliding groove (24).

3. A diagonal bracing device for aluminium templates according to claim 1, wherein: one side of the embedded support (1) is provided with a thrust plate (11), the outer side of the thrust plate (11) is provided with a reinforcing steel bar (13), and the reinforcing steel bar (13) is spirally arranged.

4. A diagonal bracing device for aluminium templates according to claim 3, wherein: the embedded support (1) is further provided with a reinforcing rib (12), and two ends of the reinforcing rib (12) are respectively connected with the embedded support (1) and the thrust plate (11).

5. A diagonal bracing device for aluminium templates according to claim 1, wherein: the embedded support (1) is further provided with a pulling-resistant steel bar (14), and the pulling-resistant steel bar (14) faces downwards.

6. A diagonal bracing device for aluminium templates according to claim 1, wherein: the diagonal brace (6) comprises an adjusting sleeve (61), and screw rods (63) are connected to two ends of the adjusting sleeve (61) in a threaded mode.

7. A diagonal bracing device for aluminum form panels according to claim 6, wherein: the adjusting sleeve (61) is provided with an adjusting handle (62).