CN217811746U - Brickwork built-in fitting construction structures - Google Patents

Abstract

The utility model relates to a brickwork built-in fitting construction structures relates to the field of brickwork construction, and it includes pre-buried a plurality of connecting block in the wall post, every be provided with the drawknot muscle on the connecting block, set up the logical groove that supplies the drawknot muscle to pass the connecting block on the connecting block, it is adjacent be provided with the telescopic link between the connecting block, the telescopic link is extending structure, be provided with on the connecting block and fix the mounting at logical inslot with the drawknot muscle. Through mounting and telescopic link to make the drawknot muscle remove to required position, need not through the pre-buried drawknot muscle that punches, reduce because of beating the destruction that the pre-buried hole caused to the wall body by mistake, facilitate for reducing the potential safety hazard in the very big degree.

Description

Brickwork built-in fitting construction structures

Technical Field

The application relates to the field of brickwork construction, especially, relate to a brickwork built-in fitting construction structures.

Background

The structure mainly made of masonry is called masonry structure. The brick structure comprises a brick structure, a stone structure and a building block structure made of other materials, and the masonry structure is widely applied in China because the brick structure can be made of local materials, has good durability, good chemical stability and atmospheric stability, and good heat insulation performance.

When a filler wall body is built in an engineering building, a large number of holes are punched in wall columns, the tie bars are pre-buried in the holes, and the sizes of the reserved holes are easy to deviate, so that the positions of the pre-buried tie bars are staggered, great damage is caused to the built wall body, and even quality accidents such as large cracks or collapse are caused.

SUMMERY OF THE UTILITY MODEL

For reducing the potential safety hazard, this application provides a brickwork built-in fitting construction structures.

The application provides a brickwork built-in fitting construction structures adopts following technical scheme:

the utility model provides a brickwork built-in fitting construction structures, includes a plurality of connecting block, every pre-buried in the wall post be provided with the drawknot muscle on the connecting block, set up the logical groove that supplies the drawknot muscle to pass the connecting block on the connecting block, it is adjacent be provided with the telescopic link between the connecting block, the telescopic link is extending structure, be provided with on the connecting block and fix the mounting at logical inslot with the drawknot muscle.

By adopting the technical scheme, the connecting blocks and the tie bars are pre-buried in advance, and the distance between two adjacent connecting blocks is increased or reduced by adjusting the extension or shortening of the telescopic rod, so that the distance between two adjacent connecting blocks is adjusted, the distance between the tie bars on the adjacent connecting blocks meets the safety requirement, and the potential safety hazard is effectively reduced; the drawknot muscle passes the connecting block, slides to required position in leading to the inslot, fixes the drawknot muscle at leading to the inslot through the mounting to adjust the length that the drawknot muscle stretched into the wall body, satisfy the safe handling length of drawknot muscle, reduce the potential safety hazard. The drawknot muscle can be adjusted in the cooperation of mounting and telescopic link and remove to required position, accomplishes the pre-buried location of drawknot muscle fast, need not through the pre-buried drawknot muscle that punches, reduces because of the damage that the pre-buried hole of beating the mistake caused the wall body, has reduced the potential safety hazard in the very big degree.

Optionally, the telescopic link is including connecting first branch and the second branch on adjacent connecting block respectively, second branch sliding connection is in first branch, be provided with on the first branch and order about the gliding drive assembly of second branch.

Through adopting above-mentioned technical scheme, when needing to adjust the interval of adjacent drawknot muscle, through drive assembly to make second branch slide in the sliding tray, so that the connecting block slides, so that adjust the interval of adjacent connecting block, thereby realize adjusting the interval between the drawknot muscle on the adjacent connecting block, reduce because of beating the destruction that pre-buried hole caused the wall body by mistake, so that reduce the potential safety hazard.

Optionally, the driving assembly includes a screw rod rotatably connected in the first supporting rod, the screw rod is in threaded connection with the second supporting rod, and a rotating member for driving the screw rod to rotate is arranged in the first supporting rod.

Through adopting above-mentioned technical scheme, through rotating the piece to make the screw rod rotate, through the screw rod, make second branch slip, so that adjust adjacent connecting block interval, so that adjust the interval between the drawknot muscle on the adjacent connecting block, reduce because of beating the destruction that pre-buried hole caused the wall body by mistake, thereby reduced the potential safety hazard.

Optionally, the rotating part comprises a first bevel gear sleeved on the screw rod, a second bevel gear meshed with the first bevel gear is rotatably connected to the first supporting rod, and a rotating rod driving the second bevel gear to rotate is rotatably connected to the first supporting rod.

Through adopting above-mentioned technical scheme, rotate the dwang, drive second bevel gear and rotate for first bevel gear rotates, so that the screw rod rotates, for the interval between the drawknot muscle on the adjacent connecting block of adjusting provides convenience, satisfies the safe interval requirement of drawknot muscle on the adjacent connecting block.

Optionally, a guide block is arranged on the second supporting rod, a guide groove for the guide block to slide is formed in the first supporting rod, and the guide groove is formed along the length direction of the first supporting rod.

Through adopting above-mentioned technical scheme, the setting up of guide block and guide way has the guide effect, reduces the possibility that second branch produced the rotation, provides convenience for the slip of second branch.

Optionally, the fixing piece comprises a bolt screwed on the connecting block, and the bolt is used for abutting against the tie bar.

Through adopting above-mentioned technical scheme, rotate the bolt to make the bolt butt or break away from the drawknot muscle, thereby realize fixing or break away from the drawknot muscle, so that adjust the length of stretching into the wall body of drawknot muscle, in order to satisfy the safe handling length of drawknot muscle.

Optionally, calipers with scales are arranged on the first supporting rod and the second supporting rod.

Through adopting above-mentioned technical scheme, the setting of slide caliper rule can make the staff can obtain the numerical value of interval when adjusting adjacent lacing wire interval fast, adjusts into the same interval for the lacing wire and provides convenience.

Optionally, a clamping groove for clamping the caliper is formed in the first supporting rod and the second supporting rod.

Through adopting above-mentioned technical scheme, draw-in groove and slide caliper rule set up can dismouting slide caliper rule to in the slide caliper rule of different precision is changed according to actual conditions, is favorable to the distance between the adjacent connecting block of more accurate adjustment, satisfies the safe interval requirement between the lacing wire on the adjacent connecting block.

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

1. connecting blocks and tie bars are pre-buried in advance, and the distance between every two adjacent connecting blocks is increased or decreased by adjusting the extension or shortening of the telescopic rod, so that the distance between every two adjacent connecting blocks is adjusted, the distance between the tie bars on the adjacent connecting blocks meets the safety requirement, and the potential safety hazard is effectively reduced; the drawknot muscle passes the connecting block, slides to required position in leading to the inslot, fixes the drawknot muscle at leading to the inslot through the mounting to adjust the length that the drawknot muscle stretched into the wall body, satisfy the safe handling length of drawknot muscle, reduce the potential safety hazard. The fixing piece and the telescopic rod are matched to adjust the movement of the tie bar to a required position, so that the pre-embedding and positioning of the tie bar can be quickly completed, the tie bar does not need to be pre-embedded through punching, the damage to a wall body caused by mistaken pre-embedding of holes is reduced, and the potential safety hazard is greatly reduced;

2. when the distance between the adjacent tie bars needs to be adjusted, the second supporting rod slides in the sliding groove through the driving assembly, so that the connecting blocks slide, the distance between the adjacent connecting blocks is adjusted, the distance between the tie bars on the adjacent connecting blocks is adjusted, the damage to a wall body caused by mistakenly embedding holes is reduced, and the potential safety hazard is reduced;

3. draw-in groove and slide caliper rule set up can dismouting slide caliper rule to change the slide caliper rule of different precision according to actual conditions, be favorable to the distance between the adjacent connecting block of more accurate adjustment, satisfy the safe interval requirement between the drawknot muscle on the adjacent connecting block.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the present application.

Fig. 2 is a sectional view of the joint block in this embodiment.

Fig. 3 is a sectional view of the telescopic rod of the present embodiment.

Fig. 4 is an enlarged view of a portion a in fig. 1.

Description of the reference numerals: 1. connecting blocks; 2. stretching the ribs; 3. a through groove; 4. a telescopic rod; 41. a first strut; 42. a second support bar; 43. a sliding groove; 5. a fixing member; 51. a bolt; 52. a second thread groove; 6. a drive assembly; 61. a screw; 62. a first thread groove; 63. a rotating member; 631. a first bevel gear; 632. a second bevel gear; 7. a guide block; 8. a guide groove; 9. a caliper; 10. a card slot; 11. a sleeve; 12. rotating the rod; 13. a rotating groove; 14. a handle; 15. a pull ring; 16. rotating the groove; 17. a receiving groove.

Detailed Description

The present application is described in further detail below with reference to the attached drawings.

The embodiment of the application discloses brickwork built-in fitting construction structures, combine figure 1 and figure 2, including setting up a plurality of connecting block 1 in the wall post, connecting block 1 is arranged along vertical direction, equal sliding connection has lacing wire 2 on every connecting block 1, in this embodiment, connecting block 1 sets up to six, lacing wire 2 on every connecting block 1 sets up to two, two lacing wire 2 keep away from the one end of connecting block 1 and are 90 bendings, be provided with sleeve 11 between two lacing wire 2, sleeve 11's both ends thread bush is established on two lacing wire 2, lacing wire 2 and sleeve 11's setting can increase connection stability, also can promote lacing wire 2's anti-shearing ability, set up the logical groove 3 that supplies lacing wire 2 to pass connecting block 1 on connecting block 1, mounting 3 and lacing wire 2 one-to-one, be provided with on connecting block 1 and fix lacing wire 2 at logical 5 in logical groove 3, bolt 51 of connecting block 1 is including rotating the bolt 51 of connecting on connecting block 1, bolt 51's rotation axis is perpendicular with lacing wire 2's length direction, set up on connecting block 1 with bolt 51 screw thread fit's second 52, bolt 52 and the one end communicates with lacing wire 2, the threading 2 one end of lacing wire is close to the lacing wire 2.

Pulling the tie bar 2 to enable the tie bar 2 to slide in the through groove 3 to a required position, and rotating the bolt 51 to enable one end of the bolt 51 to abut against the tie bar 2, so that the tie bar 2 is fixed; the bolt 51 is turned so that the bolt 51 is disengaged from the lacing wire 2 so that the lacing wire 2 can slide.

Referring to fig. 1 and 3, an expansion link 4 is disposed between adjacent connecting blocks 1, and the expansion link 4 is of a telescopic structure. The telescopic rod 4 comprises a first supporting rod 41 and a second supporting rod 42 which are respectively connected to adjacent connecting blocks 1, the second supporting rod 42 is slidably connected into the first supporting rod 41, a sliding groove 43 for the second supporting rod 42 to slide is formed in the first supporting rod 41, the sliding groove 43 is formed along the length direction of the first supporting rod 41, a driving component 6 for driving the second supporting rod 42 to slide is arranged on the first supporting rod 41, the driving component 6 comprises a screw 61 rotatably connected into the first supporting rod 41, the rotating axis of the screw 61 is parallel to the length direction of the first supporting rod 41, one end of the screw 61 is rotatably connected onto the bottom wall of the sliding groove 43, a rotating groove 16 for rotating the screw 61 is formed in the first supporting rod 41, the rotating groove 16 is communicated with the sliding groove 43, the screw 61 is in threaded connection with the second supporting rod 42, and a first thread groove 62 in threaded fit with the screw 61 is formed in the second supporting rod 42.

As shown in fig. 3, a rotating member 63 for driving the screw 61 to rotate is disposed in the first support rod 41, the rotating member 63 includes a first bevel gear 631 fixedly sleeved on the screw 61, the first bevel gear 631 rotates coaxially with the screw 61, a second bevel gear 632 meshed with the first bevel gear 631 is rotatably connected in the first support rod 41, a rotation axis of the second bevel gear 632 is perpendicular to a rotation axis of the first bevel gear 631, a rotation rod 12 is rotatably connected to the first support rod 41, a rotation groove 13 for rotating the rotation rod is formed in the first support rod 41, one end of the rotation rod 12 is fixedly connected to the first bevel gear 631, the rotation rod 12 and the second bevel gear 632 rotate coaxially, a handle 14 is fixedly connected to one end of the rotation rod 12 away from the second bevel gear 632, the rotation rod 12 and the handle 14 are disposed so that the second bevel gear 632 can rotate, thereby facilitating adjustment of the distance between adjacent connecting blocks 1, a guide block 7 is fixedly connected to one end of the second support rod 42 close to the xxxx, a guide groove 8 for sliding the guide block 7 is formed in the first support rod 41, and the guide groove 8 is communicated with the sliding groove 43.

When the interval of adjacent connecting blocks 1 needs to be adjusted, the handle 14 is rotated, so that the rotating rod 12 rotates, the second bevel gear 632 rotates to drive the first bevel gear 631 to rotate, the screw rod 61 rotates, the second supporting rod 42 slides, and the interval between adjacent connecting blocks 1 is adjusted.

As shown in fig. 4, all the joint has the slide caliper 9 of taking the scale on first branch 41 and the second branch 42, the length direction of slide caliper 9 is parallel with the length direction of first branch 41, draw-in groove 10 that supplies slide caliper 9 joint is all seted up to first branch 41 and second branch 42, slide caliper 9 joint is in draw-in groove 10, slide caliper 9 one side is rotated and is connected with pull ring 15, all offer the groove 17 of accomodating that is used for accomodating pull ring 15 on first branch 41 and the second branch 42, the setting homoenergetic of pull ring 15 and draw-in groove 10 facilitates the dismouting of slide caliper 9.

Rotate pull ring 15 for pull ring 15 shifts out and accomodates groove 17, and pulling pull ring 15 drives slide caliper rule 9 and breaks away from draw-in groove 10, changes the slide caliper rule 9 of different precision according to actual conditions, with slide caliper rule 9 joint in draw-in groove 10, accomplishes slide caliper rule 9's change.

The implementation principle of the embodiment of the application is as follows: pulling the tie bar 2 to enable the tie bar 2 to slide to a required position in the through groove 3, rotating the bolt 51 to enable one end of the bolt 51 to abut against the tie bar 2, and fixing the tie bar 2; the bolt 51 is turned so that the bolt 51 is disengaged from the lacing wire 2 so that the lacing wire 2 can slide.

When the interval of adjacent connecting blocks 1 needs to be adjusted, the handle 14 is rotated, so that the rotating rod 12 rotates, the second bevel gear 632 rotates to drive the first bevel gear 631 to rotate, the screw rod 61 rotates, the second supporting rod 42 slides, and the interval between adjacent connecting blocks 1 is adjusted.

The pull ring 15 is rotated, so that the pull ring 15 moves out of the accommodating groove 17, the pull ring 15 is pulled to drive the caliper 9 to be separated from the clamping groove 10, the caliper 9 with different precisions is replaced according to actual conditions, the caliper 9 is clamped in the clamping groove 10, and the replacement of the caliper 9 is completed.

The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a brickwork built-in fitting construction structures which characterized in that: including pre-buried a plurality of connecting block (1) in the wall post, every be provided with drawknot muscle (2) on connecting block (1), set up logical groove (3) that supply drawknot muscle (2) to pass connecting block (1) on connecting block (1), it is adjacent be provided with telescopic link (4) between connecting block (1), telescopic link (4) are extending structure, be provided with on connecting block (1) and fix mounting (5) in leading to groove (3) drawknot muscle (2).

2. The masonry embedded part construction structure of claim 1, wherein: telescopic link (4) are including connecting first branch (41) and second branch (42) on adjacent connecting block (1) respectively, second branch (42) sliding connection is in first branch (41), be provided with on first branch (41) and order about gliding drive assembly (6) of second branch (42).

3. The masonry embedded part construction structure of claim 2, wherein: the driving assembly (6) comprises a screw rod (61) rotatably connected into the first supporting rod (41), the screw rod (61) is in threaded connection with the second supporting rod (42), and a rotating part (63) driving the screw rod (61) to rotate is arranged in the first supporting rod (41).

4. The masonry embedded part construction structure of claim 3, wherein: the rotating part (63) comprises a first bevel gear (631) sleeved on the screw rod (61), a second bevel gear (632) meshed with the first bevel gear (631) is connected in the first supporting rod (41) in a rotating mode, and a rotating rod (12) driving the second bevel gear (632) to rotate is connected to the first supporting rod (41) in a rotating mode.

5. The masonry embedded part construction structure of claim 3, wherein: the guide block (7) is arranged on the second supporting rod (42), a guide groove (8) for the guide block (7) to slide is formed in the first supporting rod (41), and the guide groove (8) is formed in the length direction of the first supporting rod (41).

6. The masonry embedded part construction structure of claim 1, wherein: the fixing piece (5) comprises a bolt (51) which is in threaded connection with the connecting block (1), and the bolt (51) is used for abutting against the tie bar (2).

7. The masonry embedded part construction structure according to claim 3, characterized in that: and calipers (9) with scales are arranged on the first supporting rod (41) and the second supporting rod (42).

8. The masonry embedded part construction structure of claim 7, wherein: and the first supporting rod (41) and the second supporting rod (42) are both provided with a clamping groove (10) for clamping the caliper (9).

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