CN114135105B - Built-in fitting skew resetting means - Google Patents

Abstract

The application relates to an embedded part offset resetting device, which comprises a supporting seat, a supporting frame arranged at the upper end of the supporting seat and a supporting block vertically connected to the side wall of the supporting frame in a sliding manner, wherein a correcting shaft is horizontally connected to the side wall of the supporting block in a rotating manner, and a correcting ring which can be sleeved on a reinforcing steel bar is fixed on the correcting shaft; the vertical sliding connection of lateral wall of supporting shoe has first correction pole and second correction pole, and the correction axle is located between first correction pole and the second correction pole, and when correction ring was in the horizontality, first correction pole and second correction pole butt in the both sides position of correction ring bottom. The correction ring is pushed to rotate through the first correction rod and the second correction rod, when the steel bar is bent, the correction force can be applied to the steel bar by the inner wall of the correction ring, so that the steel bar is corrected, the bending risk of the steel bar is reduced, and the quality of the building engineering is improved.

Description

Built-in fitting skew resetting means

Technical Field

The application relates to the field of resetting devices, in particular to an embedded part offset resetting device.

Background

The embedded parts are components which are embedded in the hidden engineering in advance, namely structural parts which are arranged during the pouring of the structure, and are mainly used for lap joint during the construction of the upper structure, and most of the embedded parts refer to embedded bars or embedded cast iron and the like.

In the building construction in the related art, the reinforcement needs to be pre-buried and fixed, that is, the reinforcement is vertically fixed on the external base. However, the risk of bending often occurs in the process of embedding or fixing the reinforcing steel bars, and if the reinforcing steel bars are directly poured with concrete, the structural strength of the building is affected, so that the quality of the building engineering is affected, and the improvement is needed.

Disclosure of Invention

In order to improve the quality of constructional engineering, the application provides an embedded part offset resetting device.

The application provides an embedded part offset resetting device adopts following technical scheme:

the embedded part offset resetting device comprises a supporting seat, a supporting frame arranged at the upper end of the supporting seat and a supporting block vertically connected to the side wall of the supporting frame in a sliding manner, wherein the side wall of the supporting block is horizontally connected with a correcting shaft in a rotating manner, and a correcting ring which can be sleeved on a reinforcing steel bar is fixed on the correcting shaft; the side wall of the supporting block is vertically and slidably connected with a first correcting rod and a second correcting rod, the correcting shaft is positioned between the first correcting rod and the second correcting rod, and when the correcting ring is in a horizontal state, the first correcting rod and the second correcting rod are abutted to the two sides of the bottom of the correcting ring; the support block is provided with a driving mechanism and a control mechanism, the driving mechanism is used for driving the first correction rod to vertically move, the control mechanism is used for driving the second correction rod to vertically move, and the support seat is provided with an adjusting piece for driving the support block to vertically move.

Through adopting above-mentioned technical scheme, when the reinforcing bar appears crooked, carry the supporting seat to the side of reinforcing bar, then drive parts such as correction ring through regulating part drive supporting shoe down motion to make correction ring cover establish on the reinforcing bar. And then, driving the supporting block to drive the correction ring and other components to vertically reciprocate through the adjusting piece. If the reinforcing steel bar is bent towards the first correcting rod, the correcting ring drives the correcting shaft to rotate towards the first correcting rod under the action of the reinforcing steel bar. At this time, the first correcting rod is driven to move upwards by the driving mechanism, and then the correcting ring is pushed to rotate reversely by the first correcting rod and reset, and at the same time, the inner wall of the correcting ring applies correcting force to the reinforcing steel bar, so that the reinforcing steel bar is corrected. Similarly, if the reinforcing steel bar is bent towards the second correcting rod, the second correcting rod is driven to move upwards through the control mechanism, and the reinforcing steel bar can be corrected. Through utilizing first correction pole and second correction pole to promote correction ring rotation, when the reinforcing bar appears crooked, the inner wall of correction ring can apply correction power to the reinforcing bar to realize the correction to the reinforcing bar, reduce the reinforcing bar and appear crooked risk, thereby improve the building engineering quality. Meanwhile, the mechanical correction operation of the steel bars can be realized through the design, so that the workload of constructors can be reduced, and the construction efficiency can be improved.

Optionally, the actuating mechanism includes fixed cover locate transmission gear on the correction axle, rotate connect in the drive gear of supporting shoe lateral wall and vertical being fixed in the drive rack of first correction pole lateral wall, drive gear is located transmission gear with between the drive rack, just drive gear with transmission gear with the drive rack meshes respectively.

Through adopting above-mentioned technical scheme, when the correction girdle moves the correction axle and rotates towards first correction pole, drive gear control drive gear rotates, then drive gear can control drive rack and drive first correction pole upward movement. Through setting up simple structure, simple operation's actuating mechanism, realize the rapid movement of first correction pole to improve the work efficiency when correcting the reinforcing bar. Meanwhile, the rotation of the correction ring can be utilized to control the first correction rod to automatically move vertically upwards, so that a driving source can be saved, the linkage between all parts can be improved, and the resource utilization efficiency can be improved.

Optionally, the control mechanism includes rotate connect in control gear and the vertical control rack that is fixed in the supporting shoe lateral wall of second correction pole lateral wall, control gear is located drive gear with between the control rack, just control gear with drive gear with the control rack meshes respectively.

Through adopting above-mentioned technical scheme, when correction girdle moves the correction axle and rotates towards the second correction pole, drive gear drive control gear rotates, then control gear can drive control rack and drive the upward movement of second correction pole. Through setting up succinct, the convenient control mechanism of operation of structure, realize the rapid movement of second correction pole to improve the work efficiency when correcting the reinforcing bar. Similarly, the rotation of the correction ring can be utilized in the design, the second correction rod is controlled to automatically move vertically upwards, a driving source can be saved, the linkage between all parts can be improved, and the resource utilization efficiency can be improved.

Optionally, heating rings are respectively fixed on two side surfaces of the correction ring, and the heating rings and the correction ring are concentric.

Through adopting above-mentioned technical scheme, through setting up the heating ring, realize the heating to the reinforcing bar, can conveniently correct the correction of ring to the reinforcing bar, can improve correction efficiency and effect again.

Optionally, the inner wall of the correction ring is fixed with a plurality of friction blocks along the circumferential direction of the correction ring.

Through adopting above-mentioned technical scheme, through setting up the friction disc, when correction ring drives the vertical reciprocating motion of friction disc, the friction disc rubs with the reinforcing bar to realize the self-heating to the reinforcing bar, further improve correction efficiency.

Optionally, the supporting seat is C-shaped, just semicircular guide way has been seted up along its circumference direction to the upper surface of supporting seat, the bottom of support frame is fixed with the guide block, just guide block sliding fit in the guide way, be provided with on the supporting seat and be used for the drive the gliding management and control mechanism of support frame.

Through adopting above-mentioned technical scheme, through setting up the support frame that can slide for parts such as correction ring can round reinforcing bar circumference motion. At this time, the correction ring can apply the correction force of all directions to the reinforcing bar to improve the correction effect. Meanwhile, the correction ring can correct the reinforcing steel bars in different bending directions, so that the use suitability of the resetting device is improved.

Optionally, the control mechanism includes being fixed in motor on the supporting seat, fixed cover is located control gear on the output shaft of motor and be fixed in the curved control rack of support frame lateral wall, control rack and control gear engagement.

Through adopting above-mentioned technical scheme, managing the gear through motor drive and rotate, then managing and controlling and the gear can drive management and control rack and drive the support frame motion. Through setting up simple structure, simple operation's management and control mechanism, realize the fast movement of parts such as support frame and correction ring, and then improve the work efficiency when correcting the reinforcing bar.

Optionally, the lateral wall horizontal sliding connection of supporting shoe has the side to be the correction frame of opening form, the lateral wall horizontal sliding connection of supporting shoe has can get into to correct the inboard correction piece of frame, be provided with driving piece and control on the supporting shoe, the driving piece is used for the drive correct frame horizontal movement, the control is used for the drive correct piece horizontal movement.

Through adopting above-mentioned technical scheme, if the crooked degree of reinforcing bar is great, carry the supporting seat to the side of reinforcing bar, then drive correction frame and correction piece downstream through the supporting shoe to make the crooked position of reinforcing bar aim at correction piece. Subsequently, the correcting rack is driven to move towards the correcting block by the driving piece, and meanwhile, the correcting block is driven to move towards the correcting rack by the control piece. At this time, the correction block applies correction force to the arched end of the reinforcing steel bar, the correction frame applies tightening force to the reinforcing steel bar, and then the reinforcing steel bar can be corrected under the action of the correction block and the correction frame. The design can realize preliminary correction and predistortion operation of the steel bars, can facilitate the accurate correction operation of the correction ring on the steel bars, and can improve the working efficiency of correcting the steel bars.

Optionally, the side wall of the correction frame and the side wall of the correction block are respectively provided with a positioning groove for clamping the reinforcing steel bars.

Through adopting above-mentioned technical scheme, through setting up the constant head tank, realize the location to the reinforcing bar, reduce the reinforcing bar and follow the risk that the correction piece deviate from with the correction frame to improve correction efficiency and effect to the reinforcing bar.

Optionally, the bottom of supporting seat sets up by a plurality of auto-lock truckles.

Through adopting above-mentioned technical scheme, the person of facilitating the use carries and moves resetting means to improve the convenience of use.

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

the first correcting rod and the second correcting rod push the correcting ring to rotate, when the steel bar is bent, the inner wall of the correcting ring can apply correcting force to the steel bar, so that the steel bar is corrected, the risk of bending the steel bar is reduced, and the quality of the building engineering is improved;

by arranging the heating ring, the steel bar is heated, so that the correction of the correction ring on the steel bar is convenient, and the correction efficiency and effect can be improved;

preliminary correction operation and predistortion operation are carried out on the steel bars through the correction frame and the correction block, so that accurate correction operation of the correction ring on the steel bars can be facilitated, and the working efficiency of correcting the steel bars can be improved.

Drawings

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

Fig. 2 is a schematic structural view of a support block in an embodiment of the present application.

Fig. 3 is a partial cross-sectional view of an embodiment of the present application.

Fig. 4 is an enlarged schematic view of the area a in fig. 2.

Fig. 5 is a schematic structural view of a driving mechanism and a control mechanism in the embodiment of the present application.

Reference numerals illustrate: 1. a support base; 2. self-locking castor; 3. a support frame; 4. a support block; 5. an adjusting member; 6. a correction rack; 7. a correction block; 8. a positioning groove; 9. a driving member; 10. a control member; 11. a guide groove; 12. a guide block; 13. a control mechanism; 131. a motor; 132. controlling the gear; 133. controlling the rack; 14. a correction shaft; 15. a correction ring; 16. a first correction lever; 17. a second correction lever; 18. a driving mechanism; 181. a transmission gear; 182. a drive gear; 183. a drive rack; 19. a control mechanism; 191. a control gear; 192. controlling a rack; 20. a friction block; 21. and heating the ring.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-5.

The embodiment of the application discloses an embedded part offset resetting device. Referring to fig. 1, the embedded part offset resetting device comprises a C-shaped supporting seat 1, and self-locking casters 2 are respectively arranged at four corners of the bottom of the supporting seat 1, so that the supporting seat 1 is convenient to carry and move. The supporting seat 1 upper end is provided with support frame 3, and the vertical sliding connection of lateral wall of support frame 3 has supporting shoe 4 to be provided with on the support frame 3 and drive the regulating part 5 of the vertical motion of supporting shoe 4.

Referring to fig. 1 and 2, the side wall of the support block 4 is horizontally slidably connected with a correction frame 6 having an opening shape on the side, and at the same time, the side wall of the support block 4 is horizontally slidably connected with a correction block 7, and the correction block 7 can enter the inner side of the correction frame 6. The side walls of the correcting rack 6 and the correcting block 7, which are close to one side of the correcting rack, are respectively provided with a positioning groove 8 for clamping the reinforcing steel bars, so that the limit of the reinforcing steel bars is realized. Meanwhile, the supporting block 4 is provided with a driving piece 9 and a control piece 10, the driving piece 9 is used for driving the correcting frame 6 to horizontally move, and the control piece 10 is used for driving the correcting block 7 to horizontally move.

Referring to fig. 2, the adjusting member 5, the driving member 9 and the control member 10 respectively adopt an air cylinder or an electric push rod, and the telescopic end of the air cylinder or the electric push rod is fixedly connected with the supporting block 4, the rectifying frame 6 or the rectifying block 7, thereby providing stable driving force for the movement of the supporting block 4, the rectifying frame 6 and the rectifying block 7.

When the bending degree of the steel bar is large, the supporting seat 1 is carried to the side of the steel bar, and then the supporting block 4 is driven by the adjusting piece 5 to drive the correction frame 6 and the correction block 7 to move downwards, so that the arched end of the steel bar is aligned to the correction block 7. Subsequently, the straightening vane 6 is driven to move toward the straightening vane 7 by the driving piece 9, and simultaneously the straightening vane 7 is driven to move toward the straightening vane 6 by the control piece 10, and the reinforcing bars are clamped into the positioning grooves 8.

At this time, the correction block 7 applies a correction force to the arched end of the reinforcing bar, the correction frame 6 applies a tightening force to the reinforcing bar, and then the reinforcing bar can be corrected under the action of the correction block 7 and the correction frame 6. Then, the heights of the supporting blocks 4, the correcting frames 6 and other parts are adjusted through the adjusting parts 5, so that the preliminary correction operation of different positions of the reinforcing steel bars is realized.

Referring to fig. 1 and 3, the upper surface of the support base 1 is provided with a semicircular guide groove 11 along the circumferential direction thereof, the bottom of the support frame 3 is integrally formed with a guide block 12, and the guide block 12 is slidably fitted in the guide groove 11, so that the support frame 3, the correction block 7, and the like can move around the reinforcing bars. Meanwhile, a control mechanism 13 for driving the support frame 3 to slide is arranged on the support seat 1 so as to realize the rapid adjustment of the positions of the correction block 7 and the like, thereby realizing the rapid correction of the reinforcing steel bars with different bending angles.

Referring to fig. 3, the control mechanism 13 includes a motor 131 fixedly connected to the support base 1, and a control gear 132 is fixedly sleeved on an output shaft of the motor 131. Meanwhile, the side wall of the supporting frame 3 is fixedly connected with a circular arc-shaped control rack 133, and the control rack 133 is meshed with the control gear 132. When the motor 131 drives the control gear 132 to rotate, the control gear 132 can drive the control rack 133 to drive the support frame 3 and other components to move.

Referring to fig. 3 and 4, the side wall of the support block 4 is horizontally rotatably connected with the correction shaft 14, and the correction shaft 14 is located above the correction frame 6. The end of the correcting shaft 14 is fixedly connected with a correcting ring 15, and the correcting ring 15 can be sleeved on the reinforcing steel bars. Meanwhile, the center line of the correction ring 15 and the center line of the positioning groove 8 are arranged in a staggered mode, and the center line of the correction ring 15 is closer to the supporting block 4, so that the risk that the correction ring 15 interferes with the reinforcing steel bar when the correction frame 6 corrects the reinforcing steel bar is reduced.

Referring to fig. 4 and 5, the side wall of the support block 4 is vertically slidably connected with a first correction lever 16 and a second correction lever 17, and the first correction lever 16 and the second correction lever 17 are symmetrically distributed on both sides of the correction shaft 14. When the correction ring 15 is in the horizontal state, the upper end portions of the first correction lever 16 and the second correction lever 17 are respectively abutted against the bottom surface of the correction ring 15. Meanwhile, the supporting block 4 is provided with a driving mechanism 18 and a control mechanism 19, the driving mechanism 18 is used for driving the first correcting rod 16 to vertically move, and the control mechanism 19 is used for driving the second correcting rod 17 to vertically move.

When the steel bars need to be accurately corrected, the supporting seat 1 is carried to the side of the steel bars, then the supporting block 4 is driven by the adjusting piece 5 to drive the correcting ring 15 and other parts to move downwards, and the correcting ring 15 is sleeved on the steel bars. Subsequently, the supporting block 4 is driven by the adjusting piece 5 to drive the components such as the correcting ring 15 to vertically reciprocate.

If the reinforcing steel bar is bent toward the first correcting bar 16, the correcting ring 15 drives the correcting shaft 14 to rotate toward the first correcting bar 16 by the reinforcing steel bar. At this time, the first correction lever 16 is driven to move upward by the driving mechanism 18, and then the first correction lever 16 pushes the correction ring 15 to rotate reversely and return. At the same time, the inner wall of the straightening ring 15 applies a straightening force to the reinforcing steel bar, thereby straightening the reinforcing steel bar.

If the reinforcing bars are bent toward the second correcting bar 17, the correcting ring 15 drives the correcting shaft 14 to rotate toward the second correcting bar 17 by the reinforcing bars. At this time, the second correction lever 17 is driven to move upward by the control mechanism 19, and then the second correction lever 17 pushes the correction ring 15 to rotate reversely and return. At the same time, the inner wall of the straightening ring 15 applies a straightening force to the reinforcing steel bar, thereby straightening the reinforcing steel bar.

Referring to fig. 4 and 5, the driving mechanism 18 includes a driving gear 181 fixedly sleeved on the correction shaft 14, a driving gear 182 is rotatably connected to a side wall of the support block 4, and the driving gear 182 is engaged with the driving gear 181, so that the driving gear 181 can drive the driving gear 182 to rotate. The side wall of the first correction rod 16 is vertically and fixedly connected with a driving rack 183, the driving gear 182 is located between the transmission gear 181 and the driving rack 183, and the driving gear 182 is meshed with the driving rack 183, so that the driving gear 182 can control the driving rack 183 to drive the first correction rod 16 to vertically move.

Referring to fig. 4 and 5, the control mechanism 19 includes a control gear 191 rotatably coupled to a sidewall of the support block 4, and the control gear 191 is engaged with the transmission gear 181 such that the transmission gear 181 can drive the control gear 191 to rotate. Meanwhile, a control rack 192 is vertically and fixedly connected to the side wall of the second correction rod 17, a control gear 191 is located between the transmission gear 181 and the control rack 192, and the control gear 191 is respectively meshed with the transmission gear 181 and the control rack 192, so that the control gear 191 can drive the control rack 192 to drive the second correction rod 17 to vertically move.

If the reinforcing bars are bent toward the first correction rod 16, the correction ring 15 drives the correction shaft 14 to rotate toward the first correction rod 16 during the vertical movement of the correction ring 15. At this time, the driving gear 181 controls the driving gear 182 and the control gear 191 to rotate, and then the driving gear 182 controls the driving rack 183 to move the first correcting lever 16 upward, and the control gear 191 controls the control rack 192 to move the second correcting lever 17 downward. At this time, the first correcting rod 16 pushes the correcting ring 15 to reversely rotate and reset, so that the inner wall of the correcting ring 15 applies a correcting force to the reinforcing steel bar, and the reinforcing steel bar is corrected.

If the reinforcing bars are bent toward the second correcting bar 17, the correcting ring 15 drives the correcting shaft 14 to rotate toward the second correcting bar 17 during the vertical movement of the correcting ring 15. At this time, the driving gear 181 controls the driving gear 182 and the control gear 191 to rotate, and then the driving gear 182 controls the driving rack 183 to move the first correcting lever 16 downward, and the control gear 191 controls the control rack 192 to move the second correcting lever 17 upward. At this time, the second correcting rod 17 pushes the correcting ring 15 to reversely rotate and reset, so that the inner wall of the correcting ring 15 applies a correcting force to the reinforcing steel bar, and the reinforcing steel bar is corrected.

Referring to fig. 4, the inner wall of the correction ring 15 is fixedly connected with a plurality of friction blocks 20 along the circumferential direction thereof, and when the correction ring 15 is set to move, the friction blocks 20 and the reinforcing steel bars generate heat by friction, thereby realizing the heating of the reinforcing steel bars and facilitating the rapid correction of the reinforcing steel bars. Meanwhile, the heating rings 21 are fixedly connected to the surfaces of the two sides of the correction ring 15 respectively, and the heating rings 21 and the correction ring 15 are concentric, so that further heating of the reinforcing steel bars is realized, and rapid correction of the reinforcing steel bars is facilitated.

The implementation principle of the embedded part offset resetting device provided by the embodiment of the application is as follows: when the reinforcing steel bar needs to be corrected, the part with larger bending of the reinforcing steel bar is initially corrected through the correction frame 6 and the correction block 7. Then, the steel bars are accurately corrected through the inner wall of the correction ring 15, so that the risk of bending of the steel bars is reduced, and the quality of the construction engineering is improved.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. An embedded part offset resetting device is characterized in that: the support comprises a support seat (1), a support frame (3) arranged at the upper end of the support seat (1) and a support block (4) vertically connected to the side wall of the support frame (3) in a sliding manner, wherein a correction shaft (14) is horizontally connected to the side wall of the support block (4) in a rotating manner, and a correction ring (15) capable of being sleeved on a steel bar is fixed on the correction shaft (14);

the side wall of the supporting block (4) is vertically and slidably connected with a first correcting rod (16) and a second correcting rod (17), the correcting shaft (14) is positioned between the first correcting rod (16) and the second correcting rod (17), and when the correcting ring (15) is in a horizontal state, the first correcting rod (16) and the second correcting rod (17) are abutted to two side positions of the bottom of the correcting ring (15);

the support block (4) is provided with a driving mechanism (18) and a control mechanism (19), the driving mechanism (18) is used for driving the first correcting rod (16) to vertically move, the control mechanism (19) is used for driving the second correcting rod (17) to vertically move, and the support seat (1) is provided with an adjusting piece (5) used for driving the support block (4) to vertically move;

the support seat (1) is C-shaped, a semicircular guide groove (11) is formed in the upper surface of the support seat (1) along the circumferential direction of the support seat, a guide block (12) is fixed at the bottom of the support frame (3), the guide block (12) is in sliding fit in the guide groove (11), and a control mechanism (13) for driving the support frame (3) to slide is arranged on the support seat (1);

the control mechanism (13) comprises a motor (131) fixed on the supporting seat (1), a control gear (132) fixedly sleeved on an output shaft of the motor (131) and an arc-shaped control rack (133) fixed on the side wall of the supporting frame (3), wherein the control rack (133) is meshed with the control gear (132).

2. The embedded part offset resetting device according to claim 1, wherein: the driving mechanism (18) comprises a transmission gear (181) fixedly sleeved on the correcting shaft (14), a driving gear (182) rotatably connected to the side wall of the supporting block (4) and a driving rack (183) vertically fixed to the side wall of the first correcting rod (16), wherein the driving gear (182) is located between the transmission gear (181) and the driving rack (183), and the driving gear (182) is meshed with the transmission gear (181) and the driving rack (183) respectively.

3. The embedded part offset resetting device according to claim 2, wherein: the control mechanism (19) comprises a control gear (191) rotatably connected to the side wall of the supporting block (4) and a control rack (192) vertically fixed to the side wall of the second correcting rod (17), the control gear (191) is located between the transmission gear (181) and the control rack (192), and the control gear (191) is meshed with the transmission gear (181) and the control rack (192) respectively.

4. The embedded part offset resetting device according to claim 1, wherein: heating rings (21) are respectively fixed on the two side surfaces of the correction ring (15), and the heating rings (21) and the correction ring (15) are concentric.

5. The embedded part offset resetting device according to claim 4, wherein: the inner wall of the correction ring (15) is fixed with a plurality of friction blocks (20) along the circumferential direction of the correction ring.

6. The embedded part offset resetting device according to claim 1, wherein: the side wall horizontal sliding connection of supporting shoe (4) has side to be correction frame (6) of opening form, the side wall horizontal sliding connection of supporting shoe (4) has can get into correction frame (6) inboard correction piece (7), be provided with driving piece (9) and control piece (10) on supporting shoe (4), driving piece (9) are used for the drive correction frame (6) horizontal movement, control piece (10) are used for the drive correction piece (7) horizontal movement.

7. The embedded part offset resetting device according to claim 6, wherein: the side wall of the correction frame (6) and the side wall of the correction block (7) are respectively provided with a positioning groove (8) for clamping in the reinforcing steel bars.

8. The embedded part offset resetting device according to claim 1, wherein: the bottom of the supporting seat (1) is provided with a plurality of self-locking casters (2).

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