KR101096604B1 - Anti-slip rebar spacer for the upper horizontal rebar - Google Patents

Abstract

PURPOSE: A rebar spacer for preventing overturn for upper horizontal rebar is provided to prevent the overturn of a rebar spacer by supporting the rebar spacer more stably, and reduce storage and logistics costs. CONSTITUTION: A rebar spacer for preventing overturn for upper horizontal rebar is as follows. Hinge holes are formed on left and right sides of the lower end of a leg unit(41). Folder-type auxiliary legs(50) are installed to be symmetric by a hinge pin(51) inserted into the hinge hole. A protrusion(52) hanging on a vertical rib(43) is formed on the other end of the auxiliary leg. Folding pieces(53,54) hanging on the side(45) of the leg unit where the auxiliary leg is unfolded are formed on the upper central part of the auxiliary leg.

Description

Anti-slip rebar spacer for the upper horizontal rebar}

The present invention relates to an anti-fall rebar spacer for an upper horizontal reinforcing bar, and more particularly, a rebar spacer for supporting an upper horizontal reinforcing bar (upper) applied to a slab of reinforced concrete (RC) from an upper horizontal reinforcing bar. An anti-conduction reinforcing bar spacer for an upper horizontal reinforcing bar to maintain the coating thickness of reinforcing bars by preventing them from falling out.

In general, rebars used in reinforced concrete buildings should be coated with the appropriate thickness by concrete to secure the bond strength with the concrete and to secure the aggregate flow between the reinforcement and the formwork when placing concrete. Reinforcing steel, which is vulnerable to corrosion by heavy moisture, is prevented from contacting with the atmosphere, preventing corrosion of steel and greatly affecting the life of the building.

In addition, since the rebar is suddenly degraded at a high temperature (approximately 600 degrees) (approximately half of the yield point), it is necessary to secure the appropriate concrete cover thickness of the rebar so that the rebar is not directly exposed to fire in case of fire. It will have a significant impact on safety.

In order to secure the cover thickness of the reinforcing bar as described above, rebar spacers are used between the various rebars and formwork used in slabs, walls, columns, and beams to maintain a constant gap. Such rebar spacers are made of plastic, high-strength concrete, or It is made of mortar, steel bar, steel plate and the like.

In particular, the conventional reinforcing bar spacer used to secure the cover thickness of the upper horizontal reinforcing bar used in the slab of the building as shown in Figures 1 to 3 of the leg portion 21 is built on the upper surface of the formwork (10) The upper horizontal reinforcing bar 12 is fitted with a "U" -shaped reinforcing bar 22 is formed, the elastic locking portion 23, 24 for preventing the separation of the upper horizontal reinforcing bar 12 is formed It was formed to be inclined inward from the left and right upper end of the reinforcing bar 22, horizontal ribs 25, 26 to prevent the lateral flow of the upper horizontal rebar 12 on the inner wall surface of the reinforcing bar 22 It was formed.

However, the conventional reinforcement spacer 20 has a slight elastic force when external force is applied in the longitudinal direction of the upper horizontal reinforcing bar 12 during reinforcement work or concrete placing work, as shown in FIG. Although there is movement but is not completely conducted by the elastic catching parts 23 and 24, but there is a holding force in the left or right direction, which is a direction rotated from the center of the upper horizontal rebar 12, as shown in FIG. When the external force is applied, there was a problem that is easily rotated and fell.

That is, since the resilient latching portions 23 and 24 formed in the conventional rebar spacer 20 are formed to have a cross section that is continuous in the same direction as the longitudinal direction of the upper horizontal rebar 12, the rebar spacer 20 is formed. In the case of receiving force in the front and rear direction, there is a force held by the elastic catching parts 23 and 24, but is very vulnerable to the force acting in the rotational direction at the center of the upper horizontal reinforcing bar 12, in particular, the leg part 21. Since the height is higher than the left and right width, there was a problem that falls easily with a little force.

When the rebar spacer 20 supporting the upper horizontal rebar 12 is inverted as described above, there is a problem in that the concrete coating thickness of the upper horizontal rebar 12 is not secured.

In addition, since the reinforcement spacer 20 is not visible during the concrete pouring operation, the conduction of the reinforcement spacer 20 cannot be found, so it is more important to firmly fix the reinforcement spacer 20 before the concrete pouring operation.

The present invention has been made to solve the above problems, the object of which is to provide an anti-conduction reinforcement spacer for the upper horizontal reinforcing bar that can prevent the fall of the reinforcing bar spacer for supporting the upper horizontal reinforcement used in reinforced concrete buildings Is in.

In order to achieve the object of the present invention, hinge holes are formed at the left and right sides of the lower end of the leg portion, and the fold-type auxiliary legs are symmetrically installed by the hinge pins inserted into the hinge holes, and the latching jaws caught by the vertical ribs are fold-type auxiliary. It is formed on the other end of the leg, and the bending piece that is caught on the side end of the leg in the position where the fold auxiliary legs are horizontally spread is formed in the upper center of the fold auxiliary legs to provide an anti-conduction reinforcement spacer for the upper horizontal reinforcement.

The present invention as described above has the effect of supporting the reinforcement spacers more stably because the support width of the reinforcement spacers can be widened by the foldable auxiliary legs installed at the lower left and right sides of the reinforcement spacers. When the reinforcement spacer coupled to the horizontal reinforcement is applied in the lateral direction has an effect that can prevent the reinforcement of the reinforcement spacer by the foldable auxiliary legs that are expanded and fixed.

 Furthermore, since it is configured to fold or unfold the clamshell, it is effective to reduce the space occupied by the reinforcement spacers and to reduce the storage and logistics costs. Since the upper horizontal reinforcing bar can be combined with stepping-out of the auxiliary legs, it is possible to perform the reinforcing bar installation work more conveniently and quickly in a narrow place.

In addition, by unfolding the folding legs and maintaining the unfolded state of the folding legs by simply bending the bending pieces formed on the vertical plate using a hammer or a plier, the work is very quick and convenient. You can expect the effect to shorten.

In addition, if the bending piece formed on the vertical plate of the folding leg is not bent or needs reinforcement, the fixing pin is inserted through the locking hole formed in the leg of the folding leg and the reinforcing spacer. Since the legs can be fixed horizontally, fixing of the foldable subsidiary legs is more robust and convenient, and the bending part and the downward bending part of the fixing pin inserted into the locking hole are located on the side of the locking groove and the vertical plate, respectively. If it is, there is an effect that can prevent the release of the fixing pin.

In addition, only the bottom apex of the circular support formed at the end of the clamshell is separated from the formwork and is exposed to the concrete surface because only the lower apex of the circular support part is formed in line contact with the formwork. There is also an effect to protect the clamshell legs by minimizing the parts.

1 is a perspective view showing a conventional reinforced spacer
Figure 2 is a side view showing a conventional reinforced spacer
Figure 3 is a front sectional view showing a conventional reinforced spacer
Figure 4 is a perspective view of the folded state showing a first embodiment according to the present invention
Figure 5 is a perspective view of the expanded state showing a first embodiment according to the present invention
Figure 6 is a front view of the expanded state showing a first embodiment according to the present invention
Figure 7 is a perspective view of the expanded state showing a second embodiment according to the present invention
8 is an exploded perspective view showing a second embodiment according to the present invention;
Figure 9 is an exploded perspective view of the main portion showing a second embodiment according to the present invention

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

4 to 6 show a first embodiment according to the present invention, as shown in the upper portion of the upper portion of the leg 41, which is erected on the upper surface of the formwork 30 for placing the reinforced concrete slab The rebar coupling part 42 into which the horizontal reinforcement 32 is inserted and seated is formed, and has a normal reinforcement spacer 40 structure in which vertical ribs 43 are formed in the center of the leg part 41.

In addition, hinge holes 44 are formed at the left and right sides of the lower end of the leg portion 41, and the foldable auxiliary legs 50 are symmetrically installed by the hinge pins 51 inserted into the hinge holes 44, A latching jaw 52 that is caught by the vertical ribs 43 is formed at the other end of the foldable auxiliary leg 50, and the lateral end 45 of the leg part 41 is positioned at the horizontally extended position of the foldable auxiliary leg 50. Bent pieces 53 and 54 are formed on the upper center portion of the foldable auxiliary leg 50.

In addition, the hinge pin 51 has a flat head, and the push nut 80 may be coupled to the front end to prevent it from being pulled out, but is not necessarily limited to the coupling by the push nut 80. After forming the annular groove at the tip of the hinge pin 51 as shown in the following, the E-ring or the stop ring for the shaft is combined or the hole penetrated in the direction perpendicular to the shaft at the tip of the hinge pin 51, and then R-ring or split pin, Can be fixed with a spring pin, etc.

The foldable auxiliary leg 50 includes two vertical plates 57 and 58 spaced apart from each other with pin holes 55 and 56 coincident with the hinge hole 44 formed in the leg portion 41. A connecting plate 59 connecting the two vertical plates 57 and 58 across the lower ends of the two vertical plates 57 and 58, and a vertical plate 57 so as to have the same center as the pinholes 55 and 56. The anti-interference round parts 60 and 61 formed at one corner portion of the 58 and the circular support part 62 formed at the other end of the vertical plates 57 and 58 to be in line contact with the formwork 30. 63).

7 to 9 show a second embodiment according to the present invention, and as shown therein, the main part has the same configuration as the first embodiment, and in this configuration, the foldable auxiliary legs 50 are horizontal. Locking holes 64, 65 and 46 are formed in the vertical plates 57 and 58 and the leg portions 41 at the centers, and the locking holes 64, 65 and 46 are aligned. The fixing pin 70 is inserted into the configuration.

The fixing pin 70 may be used to fix the unfolded state of the folding auxiliary legs 50 using the fixing pin 70 in a place where it is difficult to bend the bending pieces 53 and 54 in the field. And, bending the bending piece (53) (54) and then inserting the fixing pin (70), it is possible to more solid fixing.

In addition, a “L” shaped bending portion 72 is formed at one end of the fixing pin 70 at the upper end of the vertical plates 57 and 58, and is downwardly applied to the side surfaces of the vertical plates 57 and 58. The bent portion 74 is formed at the end of the bending portion 72.

In addition, the engaging grooves 66 and 67 are formed at the upper ends of the vertical plates 57 and 58 so that the bending portions 72 formed on the fixing pins 70 are seated.

Hereinafter, the operation according to the present invention will be described in detail with reference to the accompanying drawings.

In the first embodiment according to the present invention, as shown in the accompanying drawings, Figures 4 to 6, the foldable auxiliary legs 50 are brought into the field in the state mounted on the lower left and right sides of the reinforcing spacer 40, the reinforcing spacer 40 When folding the clamshell auxiliary legs (50) hinged to the upper side, since the clamshell auxiliary legs (50) are erected vertically, it is possible to reduce the volume occupied by the rebar spacer (40), which is the rebar spacer The space occupied by the 40 can be reduced to reduce storage and logistics costs.

In addition, when the foldable auxiliary legs 50 are folded vertically, the foldable auxiliary legs 50 are reinforced by spacers 40 and 61 formed at the corners of the vertical plates 57 and 58. It is possible to prevent interference with the vertical rib 43 formed in the).

On the other hand, before the reinforcing bar spacer 40 brought into the site to the upper horizontal reinforcing bar 32, a folding auxiliary bridge coupled to the left and right sides of the lower end of the leg 41 of the reinforcing bar spacer 40 by the hinge pin 51 ( When one of the horizontal 50 is unfolded, the engaging jaw 52 formed in the foldable auxiliary leg 50 is in close contact with the vertical surface of the vertical rib 43 formed in the reinforcing spacer 40.

At this time, when the bending pieces 53 and 54 formed at the upper center of the vertical plates 57 and 58 are bent in a direction facing each other, the bending pieces 53 and 54 are at the sides of the legs 41. While holding the end 45, the clamshell secondary leg 50 is fixed in a horizontally extended state.

Thus, bending the bending pieces 53 and 54 can be bent simply with a hammer or a pliers.

Then, while unfolding the remaining non-fixed clamshell auxiliary legs (50) slightly while entering the lower horizontal reinforcing bar (not shown) at the same time while the reinforcing bar spacer 40 slightly laid down the upper horizontal reinforcing bar (32) When combined to stand and then unfold the other unfolded clamshell auxiliary legs (50) horizontally, the reinforcement spacer 40 is erected perpendicular to the upper surface of the formwork (30), the locking step formed in the clamshell auxiliary legs (50) 52 is horizontal while being caught by the vertical surface of the vertical rib 43.

At this time, when the bent piece 53, 54 formed at the center of the upper end of the vertical plate 57, 58 of the clamshell auxiliary leg 50 in a direction facing each other, the bent piece 53 ( 54 is caught by the side end portion 45 of the leg portion 41, the foldable auxiliary leg 50 is fixed in a horizontal state.

That is, by folding the folding auxiliary legs 50, which are hinged to the left and right sides of the lower ends of the reinforcing spacers 40, and bending the bending pieces 53 and 54 inward, the folding auxiliary legs 50 are It will stay expanded.

At this time, the lower apex portions of the circular support parts 62 and 63 formed at the ends of the clamshell auxiliary legs 50 are in linear contact with the upper surface of the formwork 30, and then the circular support parts 62 and 63 to the cast concrete surface. At the same time to minimize the exposure at the same time widening the lower support width of the reinforcement spacer 40 to support the reinforcement spacer 40 more stably.

In addition, the connecting plate 59 constituting the clamshell auxiliary leg 50 acts to connect the vertical plates 57 and 58 which are spaced apart from the front and rear sides, and at the same time, the rigidity of the clamshell auxiliary leg 50 is provided. It will also work to improve.

In addition, when the lower horizontal reinforcement (not shown) is located near the upper horizontal reinforcement 32 or there are other obstacles, the reinforcing bar spacers 40 may be unfolded while the reinforcing spacers 40 are extended in the upper horizontal reinforcement 32. Because it can be combined with, construction in a narrow place is easy.

In the second embodiment according to the present invention, as shown in the accompanying drawings, FIGS. 7 to 9, the folding or unfolding action of the clamshell auxiliary legs 50 is the same as that of the first embodiment, except that the clamshell auxiliary legs 50 are provided. When the horizontally unfolded, the locking hole formed in the center of the locking holes 64, 65 formed in the vertical plates 57, 58 of the clamshell auxiliary legs 50 and the leg 41 of the reinforcement spacer 40 The centers of the 46 are coincident, and when the fixing pin 70 is inserted into the matching locking holes 64, 65 and 46, the folding legs 53 by the bent pieces 53 and 54 are provided. ) Can be fixed to the fixing pin 70 or the fixing pieces 70 and 54 can be more firmly fixed by the fixing pin 70.

In this case, the fixing pin 70 may be prevented from being separated from the locking holes 64, 65, 46 by the bending portion 72 and the downward bending portion 74 formed in the fixing pin 70. First, when the fixing pin 70 is inserted into the locking holes 64, 65 and 46, and then the fixing pin 70 is rotated, the bending part 72 is formed on the top of the vertical plates 57 and 58. At the same time it is seated in the engaging groove (66) 67, the downward bent portion 74 is caught on the outer surface of the vertical plate (57, 58).

That is, the fixing pin 70 is prevented from being separated in the axial direction by the downward bent portion 74 caught on the outer surface of the vertical plates 57 and 58.

On the other hand, when the reinforcement spacer 40 is coupled to the upper horizontal reinforcement 32, when the reinforcement spacer 40 receives a force in a lateral direction in which it rotates at the center of the upper horizontal reinforcement 32, the reinforcement spacer 40 Since the support width is increased by the foldable auxiliary legs 50 fixed in an unfolded state at the lower end of the leg 41, the reinforcement spacer 40 can be prevented from being turned over by the rotational force.

30: formwork 32: upper horizontal rebar
40: reinforced spacer 41: leg portion
42: reinforcing bar 43: vertical rib
44: hinge hole 45: side end
50: clamshell secondary leg 51: hinge pin
52: jam jaw 53,54: bending piece
55,56: pinhole 57,58: vertical plate
59: connecting plate 60,61: interference prevention round part
62,63: circular support 64,65,46: locking hole
66,67: locking groove 70: fixing pin
72: bending portion 74: downward bending portion
80: push nut

Claims (5)

On the upper side of the leg portion 41, which is erected on the upper surface of the formwork 30 for placing the reinforced concrete slab, the reinforcing bar coupling portion 42, into which the upper horizontal reinforcing bar 32 is fitted, is formed, and the leg portion 41 is formed. Vertical ribs 43 are formed at the center of the center, and hinge holes 44 are formed at the left and right sides of the lower ends of the leg portions 41, and are folded by hinge pins 51 inserted into the hinge holes 44. In the rebar spacer in which the auxiliary legs 50 are horizontally symmetrically installed, and the locking jaw 52 caught by the vertical ribs 43 is formed at the other end of the clamshell auxiliary legs 50.
The bending pieces 53 and 54 which are caught by the side end portions 45 of the leg portions 41 at the horizontally extended positions of the clamshell auxiliary legs 50 are formed at the upper center of the clamshell auxiliary legs 50. Anti-fall rebar spacer for the upper horizontal reinforcement, characterized in that configured. delete delete delete delete

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