CN211523529U - Embedded part of simulation tree - Google Patents

Abstract

The utility model relates to an emulation tree built-in fitting, including a plurality of pre-buried poles and cup joint the stirrup on a plurality of pre-buried poles, can dismantle on the pre-buried pole and be connected with the locating piece, be equipped with location portion on the locating piece, be equipped with the gliding restriction portion of restriction locating piece on pre-buried pole on the locating piece. Use the measuring tape to measure out the position that needs the ligature stirrup on pre-buried pole, then beat the mark, after overlapping a stirrup on pre-buried pole, slide the stirrup to being close to the position department of demarcation, then use the locating part to fix the stirrup in mark department, the locating piece passes through the restriction part and is fixed with pre-buried pole, so that the locating piece is difficult for appearing sliding on pre-buried pole, and then with the stirrup pre-fixing on pre-buried pole, so that when the stirrup in the front of the ligature, the stirrup in the back is difficult for appearing sliding, need not the staff when the ligature stirrup, fix the stirrup after fixing a position again, the efficiency when staff ligature stirrup has been improved.

Description

Embedded part of simulation tree

Technical Field

The utility model belongs to the technical field of the technique of bionical tree and specifically relates to a simulation tree built-in fitting is related to.

Background

At present, when a large-scale simulation tree is installed, an embedded part is generally arranged underground firstly, so that the embedded part is in lap joint with a framework of the simulation tree when the simulation tree is installed, the connection strength between the simulation tree and the ground is enhanced, and the simulation tree is not prone to toppling.

The existing embedded part comprises a plurality of reinforcing steel bars and a plurality of stirrups sleeved outside the reinforcing steel bars, when the embedded part is manufactured, the plurality of reinforcing steel bars are surrounded into a certain shape through a fixing frame and are placed in parallel, then the positions of the stirrups bound on the reinforcing steel bars are measured on an embedded rod by using a measuring scale, marks are made, and the intervals of the adjacent stirrups on the reinforcing steel bars are equal. When fixed stirrup, all cup joint the stirrup on the reinforcing bar in advance and slide the stirrup to the mark department of reinforcing bar to alright connect with direct reinforcement.

The above prior art solutions have the following drawbacks: when fixing the stirrup, the reinforcing bar is placed on the fixing frame so that the reinforcing bar is placed off the ground, and therefore the stirrup can be bound. However, use the mode of artifical ligature, when the stirrup of ligature in the front, the stirrup at back can slide away from predetermined position because of external reasons such as the shake of reinforcing bar to make the workman when fixed, need readjust the stirrup of ligature at back to primary importance, just can carry out the ligature, like this, can reduce the efficiency of workman's ligature stirrup, need improve this.

SUMMERY OF THE UTILITY MODEL

To the not enough of prior art existence, the utility model aims at providing a simulation tree built-in fitting.

The above utility model discloses an above-mentioned utility model purpose can realize through following technical scheme:

the utility model provides a simulation tree built-in fitting, includes a plurality of pre-buried poles and cup joints the stirrup on a plurality of pre-buried poles, the last dismantlement of pre-buried pole is connected with the locating piece, be equipped with location portion on the locating piece, be equipped with the restriction on the locating piece the gliding restriction portion of locating piece on pre-buried pole.

Through adopting above-mentioned technical scheme, use the measuring tape to measure out the position that needs the ligature stirrup on pre-buried pole, then beat the mark, after overlapping a stirrup on pre-buried pole, slide the stirrup to being close to the position department of demarcation, then use the locating part to fix the stirrup in mark department, the locating piece passes through the restriction part and is fixed with pre-buried pole, so that the locating piece is difficult for appearing sliding on pre-buried pole, and then fix the stirrup on pre-buried pole in advance, so that when the stirrup in the front of the ligature, the stirrup after is difficult for appearing sliding, need not the staff when the ligature stirrup, fix the back with the stirrup again, efficiency when staff's ligature stirrup has been improved.

The present invention may be further configured in a preferred embodiment as: the positioning block is elastically arranged, a clamping groove is formed in the positioning block in a sunken mode, and the clamping groove is matched with the embedded rod in a clamping mode.

Through adopting above-mentioned technical scheme, when fixing the locating piece in mark department, the pre-buried pole of slip is in order to with stirrup and draw-in groove joint, and then realizes the pre-fixing of stirrup.

The present invention may be further configured in a preferred embodiment as: magnetic parts are arranged on the groove walls of the clamping grooves.

Through adopting above-mentioned technical scheme, when the stirrup card was gone into in the draw-in groove, the stirrup was fixed with the magnetic part actuation, has further strengthened the joint strength between stirrup and the locating piece to make the stirrup be difficult for appearing sliding.

The present invention may be further configured in a preferred embodiment as: the positioning part comprises a limiting groove which is sunken on the positioning block, and the limiting groove is matched with the stirrup in a clamping manner.

Through adopting above-mentioned technical scheme, when the installation locating piece, directly with the locating piece card on pre-buried pole, there is certain frictional force between locating piece and the pre-buried pole to make the locating piece be difficult for sliding on pre-buried pole, locating piece and pre-buried pole have the fixed effect of preferred. When the stirrup is bound, the stirrup is tightly clamped between the positioning block and the embedded rod, the positioning block deforms under the tightening effect of the iron wire, and the stirrup is tightly bound to the embedded rod, so that the connection strength between the stirrup and the embedded rod is further enhanced.

The present invention may be further configured in a preferred embodiment as: and the positioning block is provided with a positioning groove.

Through adopting above-mentioned technical scheme, aim at the mark on the pre-buried pole with the constant head tank, through watching whether constant head tank and mark aim at to realize the accurate positioning of locating piece on the pre-buried pole.

The present invention may be further configured in a preferred embodiment as: one end of the embedded rod is fixedly connected with a bidirectional reinforcing mesh, and the embedded rod is perpendicular to the mesh surface of the bidirectional reinforcing mesh.

By adopting the technical scheme, the bidirectional reinforcing mesh can bear stress in the X direction and the Y direction on the same cross section, and the stress in the directions is borne, so that the foundation of the simulation tree is not easy to sink when the ground part of the simulation tree bears the force in the vertical direction; the embedded rod is not easy to move left and right after backfilling due to the stress in the X direction, and the embedded rod is always kept in a vertical state.

The present invention may be further configured in a preferred embodiment as: one end of the embedded rod is provided with a hook part, and the hook part is hooked on the bidirectional steel bar net.

Through adopting above-mentioned technical scheme, two-way reinforcing bar net has increased the area of contact of the tip of pre-buried pole with the soil, and through colluding pre-buried pole on two-way reinforcing bar net, can strengthen the withdrawal resistance of pre-buried pole to make the difficult condition of empting that takes place of emulation tree.

The present invention may be further configured in a preferred embodiment as: the embedded rods at the joint of the rectangular and rectangular shapes are surrounded by the plurality of embedded rods to form an even number.

By adopting the technical scheme, the shear strength of the embedded part is enhanced by increasing the strength of the corners of the embedded part, and the connection strength of the simulation tree and the embedded part is improved.

The present invention may be further configured in a preferred embodiment as: and a reinforcing rod is arranged between two adjacent corners of the embedded part, and one end of the reinforcing rod is hooked on the bidirectional reinforcing steel bar net.

Through adopting above-mentioned technical scheme, the intensity of built-in fitting has been strengthened to the stiffener, simultaneously, colludes with two-way reinforcing bar net through the one end of stiffener, has strengthened the joint strength between the built-in bar after the ligature and the two-way reinforcing bar net.

To sum up, the utility model discloses a beneficial technological effect does:

1. measuring the position of a stirrup to be bound on the embedded rod by using a measuring scale, marking, sleeving one stirrup on the embedded rod, sliding the stirrup to a position close to calibration, fixing the stirrup at the marked position by using a positioning part, fixing the positioning block with the embedded rod through a limiting part, so that the positioning block is not easy to slide on the embedded rod, and further pre-fixing the stirrup on the embedded rod, so that the later stirrup is not easy to slide when the previous stirrup is bound, and the stirrup is not required to be positioned and fixed again when a worker binds the stirrup, thereby improving the efficiency of binding the stirrup by the worker;

2. there is certain frictional force between locating piece and the pre-buried pole to make the locating piece be difficult for sliding on the pre-buried pole, locating piece and pre-buried pole have the fixed effect of preferred. When binding the stirrups, the stirrups are clamped between the positioning block and the embedded rod, the positioning block deforms under the tightening action of the iron wires, and the stirrups bind the embedded rod, so that the connection strength between the stirrups and the embedded rod is further enhanced;

3. the contact area of the end part of the embedded rod and the ground is increased through the bidirectional reinforcing bar net, the pulling resistance of the embedded rod can be enhanced through hooking the embedded rod on the bidirectional reinforcing bar net, and therefore the simulation tree is not prone to toppling.

Drawings

Fig. 1 is a schematic view of the connection relationship between the embedded part and the bidirectional reinforcing mesh in this embodiment;

fig. 2 is an enlarged schematic view of a in fig. 1.

In the figure, 1, a rod is embedded; 2. hooping; 3. positioning blocks; 31. an arcuate end; 32. a first end face; 33. a second end face; 34. a third end face; 4. a bidirectional reinforcing mesh; 5. a hook part; 6. a card slot; 7. a limiting groove; 8. a magnetic member; 9. positioning a groove; 10. a reinforcing bar; 11. a steel plate; 12. and a nut.

Detailed Description

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

Referring to fig. 1, for the utility model discloses a simulation tree built-in fitting, including the pre-buried pole 1 of a plurality of rigidities and cup joint stirrup 2 on a plurality of pre-buried poles 1, a plurality of stirrups 2 can be dismantled on the pre-buried pole 1 from the one end of pre-buried pole 1 to the equidistant placing of the other end and be connected with locating piece 3, are equipped with location portion on the locating piece 3, are equipped with the gliding restriction portion of restriction locating piece 3 on pre-buried pole 1 on the locating piece 3.

Utilize the location portion to fix stirrup 2 and pre-buried pole 1 and realize the pre-fixing of stirrup 2 to when making the pre-buried pole 1 of ligature in the front, displacement is difficult to appear in the pre-buried pole 1 of ligature behind, is favorable to accelerating the efficiency of ligature stirrup 2. The limiting part fixes the positioning block 3 and the embedded rod 1.

Referring to fig. 1, the positioning block 3 is elastically disposed, in this embodiment, the positioning block 3 is preferably a rubber block, and in other embodiments, the positioning block 3 may also be a plastic block.

Referring to fig. 1 and 2, the positioning block 3 includes an arc end 31 and a first end surface 32 opposite to the arc end 31, in this embodiment, the limiting portion is an arc-shaped slot 6 recessed on the first end surface 32, and in other embodiments, the limiting portion may also be a magnet embedded on the positioning block 3. The embedded rod 1 is matched with the clamping groove 6 in a clamping mode. The stirrup 2 and the positioning block 3 are fixed by clamping the embedded rod 1 and the clamping groove 6.

Referring to fig. 1 and 2, a magnetic member 8 is embedded on a groove wall of the clamping groove 6, in this embodiment, the magnetic member 8 is a magnet, in other embodiments, the magnetic member 8 may also be a magnet, and the magnetic member 8 further fixes the embedded rod 1 and the clamping groove 6.

Referring to fig. 1 and 2, the positioning block 3 includes a second end face 33 and a third end face 34 adjacent to the arc-shaped end 31, the second end face 33 and the third end face 34 are adjacent to each other, in this embodiment, the positioning portion is an arc-shaped limiting groove 7 recessed on the second end face 33, in other embodiments, the limiting portion may also be a clip, a magnet, or the like fixed on the positioning block 3, two ends of the limiting groove 7 penetrate through, and the limiting groove 7 is in snap fit with the stirrup 2. The two opposite groove walls of the limiting groove 7 clamp the stirrup 2 so as to fix the stirrup 2 on the positioning block 3.

Referring to fig. 1 and 2, the groove diameter of the stopper groove 7 gradually decreases from the notch to the groove bottom wall. The stirrup 2 can be further gradually clamped with the positioning slot 9.

In other embodiments, in order to reinforce the connection strength between the stirrup 2 and the positioning block 3, a magnet may be embedded in the limiting groove 7.

Referring to fig. 1 and 2, a positioning groove 9 is formed on the third end surface 34 of the positioning block 3, and the positioning groove 9 is communicated with the clamping groove 6. The positioning groove 9 is used for observing whether the stirrup 2 is aligned with the mark made on the embedded rod 1.

Referring to fig. 1 and 2, a plurality of embedded rods 1 are arranged in an even number so as to surround the embedded rods 1 at the joints where the embedded rods 1 are rectangular. The strength of the embedded part is enhanced.

Referring to fig. 1 and 2, the positioning blocks 3 are provided with a plurality of blocks, and the plurality of positioning blocks 3 are respectively located at the positions of the embedded rods 1 on one pair of opposite corners of the rectangular structure formed by enclosing the embedded rods 1. The pre-fixing of the stirrup 2 can be achieved by means of the diagonal.

Referring to fig. 1 and 2, a rigid reinforcing rod 10 is fixed between two junctions of a rectangular shape surrounded by a plurality of embedded rods 1 to reinforce the strength of the embedded part, so that the embedded part is not easy to deform when receiving a horizontal thrust. Threads are arranged on the embedded rod 1 and the reinforcing rod 10.

Referring to fig. 1 and 2, a bidirectional reinforcing mesh 4 is fixed at one end of the embedded rod 1 far away from the ground, and the embedded rod 1 is perpendicular to the mesh surface of the bidirectional reinforcing mesh 4. The contact area between the underground end of the embedded rod 1 and the ground is increased through the bidirectional reinforcing mesh 4, and then the pulling resistance of the embedded rod 1 is increased, so that the simulation tree fixed with the embedded part is not prone to toppling.

Referring to fig. 1 and 2, the bidirectional mesh reinforcement 4 includes a plurality of steel bars fixed to each other in a crisscross shape, and ends of the steel bars are hooked. The bidirectional reinforcing mesh 4 has a grip in the X-axis direction.

Referring to fig. 1 and 2, the end of the embedded rod 1 is fixed with a hook 5 coaxially with the embedded rod 1, the hook 5 is hooked on the bidirectional steel mesh 4, and the hook 5 is welded and fixed with the bidirectional steel mesh 4. The hook part 5 hooks the bidirectional reinforcing mesh 4, so that the contact area between the embedded rod 1 and the bidirectional reinforcing mesh 4 is increased.

Referring to fig. 1 and 2, steel plates 11 are inserted into ends of the embedded rods 1 far away from the bidirectional reinforcing mesh 4, so that stability of the ends of the embedded rods 1 is improved.

The working conditions and the implementation principle of the embodiment are as follows:

the pre-buried rod 1 is pre-stretched to enable the pre-buried rod 1 to have certain prestress, then a plurality of pre-buried rods 1 to be fixed are erected from the ground, then marks are made on the pre-buried rods 1 at equal intervals by using a measuring ruler and a marking pen so as to determine the fixed positions of the stirrups 2, the bidirectional reinforcing steel bar net 4 is welded with the hook parts 5 of the pre-buried rods 1, the stirrups 2 are sleeved on the pre-buried rods 1, the clamping grooves 6 are aligned to the marks, the positioning blocks 3 are clamped on the pre-buried rods 1 through the clamping grooves 6, the positioning blocks 3 are fixed with the pre-buried rods 1, the positioning grooves 9 are aligned to the marks so as to determine that the positioning blocks 3 are aligned to the marks, then the stirrups 2 are slid to be clamped into the limiting grooves 7, the stirrups 2 are clamped by two opposite groove walls of the limiting grooves 7 so that the stirrups 2 are fixed with the positioning blocks 3, and the stirrups 2 are bound and. Through such a mode, can be so that the pre-buried pole 1 of ligature after is difficult for sliding away from preset position, the workman need not the position of readjustment stirrup 2 during the ligature, is favorable to improving the efficiency of ligature.

The steel plates 11 are inserted into one ends, far away from the bidirectional reinforcing mesh 4, of the stirrups 2, the stability of the embedded rods 1 is enhanced, and the nuts 12 are screwed on the end portions of the embedded rods 1 to keep the prestress of the embedded rods 1.

And then placing the embedded part into the dug foundation pit, and backfilling concrete in the foundation pit to expose the end part of the embedded rod 1 far away from the bidirectional reinforcing mesh 4 out of the ground. So that it is fixed to the skeleton of the simulation tree.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (9)

1. The utility model provides a simulation tree built-in fitting, includes a plurality of pre-buried poles (1) and cup joints stirrup (2) on a plurality of pre-buried poles (1), its characterized in that: the embedded rod (1) is detachably connected with a positioning block (3), the positioning block (3) is provided with a positioning portion, and the positioning block (3) is provided with a limiting portion for limiting the positioning block (3) to slide on the embedded rod (1).

2. The simulated tree embedment of claim 1, wherein: locating piece (3) are elastic setting, it has draw-in groove (6) to cave in on locating piece (3), draw-in groove (6) with pre-buried pole (1) joint cooperation.

3. The simulated tree embedment of claim 2, wherein: and magnetic parts (8) are arranged on the groove wall of the clamping groove (6).

4. The simulated tree embedment of claim 1, wherein: the positioning part comprises a limiting groove (7) which is sunken on the positioning block (3), and the limiting groove (7) is in clamping fit with the stirrup (2).

5. The simulated tree embedment of claim 1, wherein: and the positioning block (3) is provided with a positioning groove (9).

6. The simulated tree embedment of claim 1, wherein: one end of the embedded rod (1) is fixedly connected with a bidirectional reinforcing mesh (4), and the embedded rod (1) is perpendicular to the mesh surface of the bidirectional reinforcing mesh (4).

7. The simulated tree embedment of claim 6, wherein: one end of the embedded rod (1) is provided with a hook part (5), and the hook part (5) is hooked on the bidirectional reinforcing mesh (4).

8. The simulated tree embedment of claim 7, wherein: the embedded rods (1) surround the reinforcing steel bars at the joint of the rectangular and rectangular shapes to form an even number.

9. The simulated tree embedment of claim 8, wherein: and a reinforcing rod (10) is arranged between two adjacent corners of the embedded part, and one end of the reinforcing rod (10) is hooked on the bidirectional reinforcing mesh (4).

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