KR100449977B1 - Connecting structure of reinforced bar for reinforced concreate - Google Patents

Abstract

The present invention relates to a deformed bar joint structure for reinforced concrete, and in particular, selecting an end of a deformed bar to be joined and forming a gushing portion by arc welding at the rib portion at least one or more of the selected end and the corrugated portion between the nodes. In this part, the complete thread is formed, and the nodes and ribs adjacent to the part are formed incomplete screws, respectively, and the strength and rigidity of the joints are increased to the coupler side by the complete and incomplete screws. As well as forming the inclined surface on the coupler end, the release bar is to be easily inserted into the coupler.

Description

Connecting structure of reinforced bar for reinforced concreate}

The present invention relates to a deformed bar joint structure for reinforced concrete, and in particular, to form a deformed part by arc welding in the corrugated part between the bar and the bar of the deformed bar to be jointed, and at the same time, to form a complete screw on the part And the incomplete screw is formed on the node and rib side (unattached part) close to the additional part, respectively, and then the end of the release bar is fastened to the coupler side through the complete and incomplete screw. To increase the maximum, as well as to form a slope at the end of the coupler to the release bar joint structure for reinforced concrete for the release bar can be easily inserted into the coupler.

Generally, the deformed bar used for reinforced concrete structures or steel reinforced concrete structures is used for reinforcement of concrete in building construction and is used as basic material for social overhead capital construction. Looking at the structure of such a release bar is formed with a certain thickness and length, in the process of forming the ring-shaped nodes in the body are formed at regular intervals arranged ribs are formed in the longitudinal direction.

In order to use the deformed bar as described above in the reinforced concrete structure and the steel reinforced concrete structure, the deformed bars must be connected to each other. For this purpose, after forming a joint structure (screw type) at the end of the deformed bar, a coupler having an internal female thread is formed. The ends of the release bar are fastened to each other through.

Looking at the joint structure of the conventional release bar as described above with reference to the accompanying drawings.

1 is a front view showing a joint structure of a conventional release bar, after forming a screw 13 in the node 11 and the rib 12 located at the end of the release bar 10, the inner peripheral surface is screwed coupler (shown) It is configured to connect the two deformed bar).

In the conventional release bar 10 having the structure as described above, since the screw 13 is formed only on the node 11 and the rib 12 of the release bar, the number of complete threads is small and the node 11 and the rib 12 are smaller. Screw 13 formed in the corresponding to an incomplete screw rather than a complete screw can be seen that the thread continuity is lacking. Therefore, when tensile and compressive forces are applied to the joints, slippage occurs and it is difficult to secure the rigidity of the joints, and stress concentration is concentrated on the screw side of the coupler, which may cause local coupler thread breakage. .

FIG. 2 is a front view showing an embodiment of a joint structure of a conventional release bar, and mechanically compresses the nodes 21 and the ribs 22 formed at the ends of the release bar 20, and then has a screw 23 thereon. The inner circumferential surface is formed so that two release bars are connected by screwed couplers (not shown).

Such deformed bars 20 may have a slight increase in mechanical strength or stiffness when mechanically compressed, but there is a concern that the original properties of the deformed bars may be changed due to changes in the structure or the brittleness of the deformed bars. In addition, since the cross-sectional areas (a) and (b) of the deformed steel bars of the threaded and unmachined threads are different from each other, the stress concentration phenomenon occurs at the boundary part when tension and compressive force are applied, and thus easily breaks. there was.

The release bar 20 as described above has a problem in that when the thread is formed by cutting when the screw 23 is formed at the end, the thread is easily brittle and the risk of breakage of the thread is increased, rolling. If the thread is formed by using the secondary compression to roll the first compressed portion has a disadvantage that the elongation of the deformed bar is reduced and the brittleness is weakened as a whole.

Figure 3 is a front view showing another embodiment of the joint structure of the conventional release bar, the end of the release bar 30 is cut into a tapered shape by a predetermined length and the screw 31 is formed on the tapered portion of the screw on the inner peripheral surface It is configured to connect two release bars by a machined coupler (not shown).

The release bar 30 has the disadvantage that the cross-sectional area of the release bar is reduced because the thread 31 is processed after cutting the end portion in a tapered shape by a predetermined length, and if the coupler is not completely tightened, complete fastening is impossible. There was a disadvantage in that the separation force applied at both ends in the axial direction.

4 is a front view showing another embodiment of a joint structure of a conventional release bar, wherein the ends of the release bar 40 including the node 41 and the ribs 42 are heated to a constant temperature, and mechanically axially of the release bar. After inflating by applying a compressive force to form a screw 43 on the tooth portion is configured so that the two release bars are connected by a coupler (not shown) the inner peripheral surface is threaded.

The deformed bar 40 increases the cross-sectional area of the deformed bar by applying heat to process the screw, so that not only the mechanical and chemical properties of the deformed bar are changed during heating, but also the stress concentration occurs in the section where the cross-sectional area changes, causing fracture. Not only has the disadvantage of being formed, but also by forming the thread by the cutting method, the brittle brittleness of the thread is strong, there is a problem that increases the risk of breakage.

On the other hand, all the joint structure of the conventional release bar as described above is not provided with a separate structure for guiding the release bar on the coupler side, the inconvenience to be combined in the state of adjusting the thread while adjusting the heavy and long release bar when tightening It was accompanied.

Therefore, the object of the present invention is devised in view of the conventional problems as described above, and form a complete screw in this portion of the gland at the same time as the gush formed by the arc welding on the corrugated portion between the node and the node of the deformed bar to be jointed Reinforcing bars to increase the strength and stiffness according to the joints by forming incomplete screws on the node and rib side close to the grate part, respectively, and fixing the end of the deformed bar to the coupler side through the full and incomplete screws. To provide a deformed bar joint structure for concrete.

Another object of the present invention is to provide a deformed bar joint structure for reinforced concrete to form an inclined surface at the coupler end so that the deformed bar can be easily inserted into the coupler.

Another object of the present invention is to form a complete screw and an incomplete screw formed on one end and the other end of the deformed bar in the opposite direction to each other by two coupler bars can be easily screwed at the same time by a coupler that rotates when fastening To provide a deformed bar joint structure for concrete.

1 is a front view showing a joint structure of a conventional release bar;

Figure 2 is a front view showing an embodiment of a joint structure of a conventional release bar;

Figure 3 is a front view showing another embodiment of the joint structure of a conventional release bar,

Figure 4 is a front view showing another embodiment of the joint structure of a conventional release bar,

5 is a cross-sectional view showing a state in which the release bar is coupled to the coupler according to the present invention;

Figure 6 is a process chart showing the process of the release bar according to the present invention.

(Explanation of symbols for the main parts of the drawing)

100; Deformed bars 110; word

120; Rib 130; Sickness

140; Full thread 150; Incomplete screw

200; Coupler 210; incline

As a means for achieving the above object, the present invention, by selecting the end of the deformed bar and at least one or more of the selected end of the node to form a grit by arc welding the same as the node height, this grate part is a complete screw An incomplete screw is formed on each of the nodes and ribs adjacent to the part, and the basic and structural features of the technical configuration include that the release bar is fastened to the coupler side by the complete and incomplete screws.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 5 is a cross-sectional view showing a state in which the release bar according to the invention coupled to the coupler, Figure 6 is a process chart showing a process of the release bar according to the present invention.

The release bar 100 of the present invention also has a constant thickness and length in the process of forming a ring-shaped node 110 in the body is formed at a predetermined interval arranged and the rib 120 is formed in the longitudinal direction, the end The basic context in which the release bar 100 is fastened to the coupler 200 by the formed screw joint structure is the same as in the related art.

The present invention selects an end of the release bar 100 to be joined as shown in FIGS. 5 and 6 and arcs equal to the node height h at the corrugated portion between the node 110 and the node at least one of the selected ends. Formation of the reinforcement 130 by welding, and the incomplete screw 150 is formed in the node 110 and the rib 120 adjacent to the reinforcement portion 140 and the complete screw 140 in the portion of the reinforcement 130, respectively, the complete screw The release bar 100 is configured to be coupled to the coupler 200 by the 140 and the incomplete screw 150, and guides an end of the release bar 100 to one end of both ends of the coupler 200. The inclined surface 210 is formed to be inclined inward.

Here, the glove 130 formed at the end of the release bar 100 eliminates the reduction of the cross section that may occur at the end of the release bar as well as the complete screw 140 when forming the complete screw 140 in the grate portion 130 It serves to overcome the notch phenomenon that can occur while the cross section is reduced.

The incomplete screw 150 formed on the node 110 and the rib 120 is concentrated under stress when an external force is applied to the joint portion of the deformed bar 100 in the axial direction by an external force applied to the joint portion of the deformed bar 100 by reducing or expanding the cross section. Disperses the phenomena to minimize the breakage that can occur at the stress concentration site.

In order to use the present invention configured as described above, as shown in FIG. 6, the bar 110 and the ribs 120 are formed on the body, and then the release bar 100 is formed. In the corrugated part between the 110 and the node, the gout 130 is formed by arc welding in the same manner as the height of the node h, and the grate 130 and the node 110 and the rib of the deformed bar 100 by cutting. 120) into a cylindrical shape.

The method for gluing of deotsal by arc welding while using CO ₂ arc welding machine (Arc Welding) and the electrode was used for solid wire rotates the release bars in a continuous welding was performed continuously.

Subsequently, a thread is formed on the end side of the release bar 100 by a rolling method. The complete thread 140 is processed in the portion of the gush 130 and the node 110 and the rib 120 close to the portion of the gush 130. Incomplete screw 150 is machined. At this time, the threads formed on both ends of the release bar 100 are formed in opposite directions to each other when the two release bars are screwed at the same time by the rotation of the coupler 200 when screwing.

When the screw (complete screw, incomplete screw) is processed through the rolling method as described above, the welding part increases the tensile strength by about 10% by the predetermined compressive force of the deformed bar 100 and the welding process occurs when the welding defect occurs in the welding process. Since the paste portion 130 is dropped off, it is easy to check whether the weld is defective.

One end of the coupler 200 is inclined to form an inclined surface 210 for guiding the release bar 100 to the inside.

As described above, the complete screw 140 is formed on the part of the grate 130, the coupler bar 100 having the incomplete screw 150 formed on the node 110 and the rib 120 and the inclined surface 210 formed at one end thereof. When each of the 200 is prepared, after placing the release bars on both ends of the coupler 200, and screwing one release bar first.

Then, when the coupler 200 is rotated in a state where the screw is coupled to one release bar 200 side, the coupler 200 is moved to the release bar side located at the other end to complete the fastening. At this time, since the release bar located on the inclined surface 210 enters along the inclined surface 210, the screw side formed in the coupler and the screw of the release bar (complete screw, incomplete screw) are easily made.

As described above, according to the present invention, at the same time as the arc forming on the corrugated portion between the node and the node of the deformed bar to be jointed, at the same time forming a complete screw on this part, and close to the part The incomplete screw is formed on the node and rib side, respectively, and the end of the release bar is fastened and fixed to the coupler side through the full and incomplete screws, so that the strength and rigidity of the joint can be maximized.

In addition, since the inclined surface is formed at the coupler end, the release bar can be easily inserted into the coupler during vertical coupling, and the coupler is rotated because one end and the other end of the release bar are formed in opposite directions. Two release bars can be screwed together at the same time.

The present invention has been described above with reference to specific preferred embodiments, but the present invention is not limited to the above embodiments and various changes and modifications may be made by those skilled in the art without departing from the gist of the present invention. Make sure you can.

Claims (2)

In the deformed bar that is formed in a row at a constant interval and at the same time at the same time and the rib is formed in the longitudinal direction, the end of the deformed bar 100 to be joined is selected and at least one of the selected end 110 and the node between the nodes In the corrugated part, the same length as the node height (h) is formed by the arc welding, and the extremity 130 is formed by the complete screw 140 on the part of the extremity 130 and the incomplete screw 150 on the node and the rib adjacent to the extremity part, respectively. Forming, the deformed bar joint structure for reinforced concrete, characterized in that the release bar 100 is fastened to the coupler 200 side by the complete screw 140 and incomplete screw 150. The method of claim 1, wherein the coupler 200 is a reinforcing bar joint structure for reinforced concrete, characterized in that the inclined surface 210 is formed to be inclined inward at either end of both ends.