KR20210010971A - Supporting unit of girder panel - Google Patents

Abstract

The present invention relates to a beam bracket for beam construction. According to the present invention, the beam bracket for beam construction supports a first form forming the bottom of fed concrete, and a second form connected to the first form by an angle to form a wall of the concrete. The beam bracket for beam construction comprises: a first support member to support the angle and a board of the first form from below; a second support member which is coupled to the first support member, and supports a board of the second form from a side; and a tight attaching means to attach the second support member towards the angle. As the second support member gets closer to the angle by the tight attaching means, the second member is tightly attached to the board of the second form, and the first support member is tightly attached to the angle and the board of the first form. According to the present invention, the beam bracket for beam construction directly supporting a board of a form using an angle to form sturdy bearing power against the load and lateral pressure of concrete can be provided.

Description

SUPPORTING UNIT OF GIRDER PANEL {SUPPORTING UNIT OF GIRDER PANEL}

The present invention relates to a beam bracket for beam construction, and more particularly, to a beam bracket for beam beam construction made to support the outer surface of a formwork.

In general, a formwork is a structure temporarily installed in order to make a concrete structure into a predetermined shape and size, and is made of plywood, rigid fiberboard, synthetic resin, aluminum panel, steel plate, and the like.

In particular, the formwork is made of plywood or other synthetic resin on the side adjacent to the concrete being poured, and a profile made of iron or other metal is added along the perimeter to ensure sufficient support strength to resist the surface pressure caused by concrete pouring. do.

However, such a formwork often occurs when concrete is poured to build a structure, in which it is impossible to construct a structure of a desired shape due to the deviation of the connection parts between the formwork due to the surface pressure of the concrete being poured. To do this, a beam bracket capable of supporting the outer surface of the formwork is widely used.

1 shows the applicant on 2011.11.10. Filed on 2013.06.24. It is a perspective view of a bow bracket supporting a formwork registered as a ruler, and FIG. 2 is a use state diagram of FIG. 1.

Referring to these drawings, a conventional beam bracket includes a vertical beam 1 and a horizontal beam 2 coupled in a direction orthogonal to the vertical beam 1. The vertical beam (1) supports the rear surface of the side form (Pn1) forming the beam, and the horizontal beam (2) is fixed to the yoke (T1) disposed along the lower side of the side form (Pn1) using nails or the like.

However, the conventional beam bracket is inconvenient to install as the horizontal beam (2) is fixed to the yoke (T1) provided with a timber or the like with nails, and it is difficult to dismantle after completion of the beam construction.

In addition, recently, a type of form (hereinafter referred to as'angle type form') in which the side form (Pm1) constituting the beam and the floor form (not shown) disposed on the floor are combined with an angle (not shown) has been widely used. In the case of, there is a problem that it is difficult to apply the conventional beam bracket as it is.

As shown in Fig. 1, in the conventional beam bracket, the horizontal beam 2 and the vertical beam 1 are made of an angle (or square pipe). Therefore, when the angle-type formwork is supported using a conventional beam bracket, the upper surface of the horizontal beam 2 forms a contact surface with the ① angle and ② the profile (or rib) of the floor formwork. And the upper surface of the vertical beam 1 forms a contact surface with the ① angle and ② the profile (or rib) of the side mold Pm1.

That is, the conventional beam bracket cannot directly support the null. However, since the load and lateral pressure of concrete is directly applied to the board of the formwork and then transmitted to the angle or profile (or rib), it can directly support not only the angle or profile (or rib), but also the side form (Pm1) and the board of the floor form. There is a demand for the development of a bow bracket.

Republic of Korea Patent Publication No. 10-1279811 (Registration date: 2013.06.24)

It is an object of the present invention to provide a beam bracket for beam construction which is made to directly support the board of a formwork in which an angle is used to form a strong supporting force against the load and lateral pressure of concrete.

The above object is, according to the present invention, as a beam bracket for beam construction for supporting a first foam forming the floor of the poured concrete, and a second foam that is connected to the first foam at an angle to form the wall of the concrete, the A first support member supporting the knurled of the first foam and the angle from below; A second support member coupled to the first support member and supporting the board of the second foam from the side; And a contact means for attaching the second support member toward the angle, and as the second support member approaches the angle by the contact means, the second support member is in close contact with the board of the second foam. , The first support member is achieved by a beam bracket for boreholes, characterized in that in close contact with the knurled and the angle of the first foam.

The contact means, a locking member rotatably caught on the angle and passing through the second support member; And a pusher that is screwed to the locking member from the opposite side of the angle and pushes the second support member toward the angle, and when a side pressure of the concrete acts on the second support member, the first support member It may be made in close contact with the board of the first foam in a direction opposite to the load direction of the concrete.

And a third support member coupled to the second support member and interposed between the locking member and the first support member, and as the second support member approaches the angle, the third support member It can be made in close contact with the angle.

The first support member may include a horizontal member coupled to the second support member and supporting the angle from below; And a first board support extending upward from the horizontal member and supporting the board of the first foam from below.

The second supporting member may include a vertical member coupled to the first supporting member and forming a passage hole through which the locking member passes; And a second knurled support extending laterally from the vertical member and supporting the knurled of the second foam from the side.

The second support member is interposed between the vertical member and the profile of the second foam, and includes a reinforcing rod for supporting the profile of the second foam from the side, and the vertical member has a seating rod on which the reinforcing rod is mounted It can be made to be formed.

According to the present invention, as the second support member gets closer to the angle by the contact means, the second support member is in close contact with the knurled of the second foam, and the first support member is in close contact with the knurled and angle of the first foam, It is possible to provide a beam bracket for beam construction that is made to directly support the board of a formwork using an angle to form a strong support for the load and side pressure of concrete.

1 is a perspective view of a conventional beam bracket for beam construction.
Figure 2 is a state of use of the conventional beam bracket for beam construction of Figure 1;
Figure 3 is a perspective view of a beam bracket for beam construction according to an embodiment of the present invention.
Figure 4 is a side view of the beam bracket for beam construction of Figure 3;
Figure 5 is a cross-sectional view showing the assembly state of the beam bracket for the beam construction of Figure 3;
6 is a cross-sectional view showing a state of use of the beam bracket for beam construction of Figure 3;
Figure 7 is a perspective view of a beam bracket for bore construction according to another embodiment of the present invention.
Figure 8 is a cross-sectional view showing a state of use of the beam bracket for beam construction of Figure 7;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, a description of a function or configuration that is already known will be omitted in order to clarify the gist of the present invention.

The beam bracket for beam construction of the present invention is made to directly support the board of the formwork in which the angle is used to form a strong supporting force against the load and side pressure of concrete.

FIG. 1 is a perspective view of a conventional beam bracket, FIG. 2 is a state diagram of the use of the conventional beam bracket of FIG. 1, FIG. 3 is a perspective view of the beam bracket for beam beam construction of the present invention, and FIG. 4 is It is a side view of the beam bracket, FIG. 5 is a cross-sectional view showing an assembly state of the beam bracket for beam construction of FIG. 3, and FIG. 6 is a cross-sectional view showing a state of use of the beam bracket for beam construction of FIG.

Formwork is a structure temporarily installed in order to make a concrete structure in a predetermined shape and size.After using a number of forms, a frame in the form of pouring concrete such as columns, floors, walls, etc. is woven, poured concrete, and then hardened. This frame is removed and this is called a formwork.

5 and 6, the first foam F1, the second foam F2 and the angle A constitute the formwork 1. The first foam (F1) forms the floor of the concrete (C) put into the formwork (1), and the second foam (F2) forms the wall of the concrete (C) put into the formwork (1).

The first form (F1) and the second form (F2) are connected by an angle (A). The first form (F1) and the second form (F2) should be understood as a division according to a position arranged with respect to the angle (A).

The first foam F1 and the second foam F2 shown in the drawings may be understood as aluminum foam. The aluminum foam is manufactured to secure sufficient support strength to resist the surface pressure caused by concrete pouring by combining a metal profile along the perimeter of the board.

A pinhole into which a circular pin is inserted is formed in the profile of the aluminum foam. In addition, ribs that prevent deformation of the knurled can be coupled to the knurled and the profile. Since aluminum foam is a known technology, detailed description will be omitted.

Hereinafter, for easy understanding of the present invention, the null of the first form (F1) is referred to as a'first null (F1A)', and the null of the second form (F2) is referred to as a'second null (F2A)'. I want to refer to it. In addition, the profile of the first form F1 will be referred to as a'first profile F1B', and the profile of the second form F2 will be referred to as a'second profile F2B'.

Of course, the beam bracket 10 for beam construction of the present invention can be applied not only to supporting the formwork 1 in which aluminum foam is used, but also to the formwork in which gang form and euro form are used.

When applied to the flow path form, the locking member 410 caught in the locking hole H of the angle A may have a shape of a hook portion to be described later. The locking hole H may mean a pinhole, and the shape of the end of the hook portion may be modified to suit the shape of the pinhole. This is because the shape of the pinhole is different between aluminum foam and euroform.

3 to 6, the beam bracket 10 for bore construction according to an embodiment of the present invention is made to support the outer surface of the formwork 1, the first support member 100, the second It is configured to include a support member 200, a third support member 300 and a contact means 400.

The first support member 100 is configured to support the first board F1A and the angle A from below, and includes a horizontal member 110 and a first board support 120.

The horizontal member 110 is provided with a square pipe, and supports the angle A from below. The lower end of the angle A and the lower end of the first profile F1B may form the same height. At this time, the horizontal member 110 supports the first profile F1B together with the angle A from below.

The horizontal member 110 supports the angle A in a state in which the longitudinal direction is substantially parallel to the horizontal direction. One end of the horizontal member 110 is coupled to the lower end side of the vertical member 210. The horizontal member 110 and the vertical member 210 may be coupled by welding.

Reference numeral S in FIG. 6 denotes a support pipe supporting the beam bracket 10 from the ground. Reference numeral 111 in FIG. 6 denotes a coupling portion for preventing the flow of the support pipe (S).

3 to 6, the first board support 120 is provided as a square pipe (or circular pipe) to support the first board F1A from below. The first knurled support 120 supports the first knurled F1A in a state in which the longitudinal direction is substantially parallel to the vertical direction.

The first board support 120 has a shape extending upward from the horizontal member 110. Accordingly, the upper surface of the first knurled support 120 is higher than the upper surface of the horizontal member 110. The lower end of the first board support 120 is coupled to the upper surface of the other end of the horizontal member 110. The first board support 120 and the horizontal member 110 may be coupled by welding.

When the first support member 100 supports the first board F1A and the angle A from below, that is, the lower end of the first angle A contacts the upper surface of the horizontal member 110, and the first In a state in which the upper surface of the knurled support 120 is in contact with the lower surface of the first knurled F1A, the horizontal member 110 is substantially parallel to the horizontal direction in its longitudinal direction.

3 to 6, the second support member 200 is configured to support the second board F2A from the side, and the vertical member 210, the second board support 220 and the reinforcing bar 230 ).

The vertical member 210 is provided with a square pipe, and is coupled to the horizontal member 110. One end of the horizontal member 110 is coupled to the lower end side of the vertical member 210. The vertical member 210 is spaced apart from the second foam (F2) and the angle (A) in the horizontal direction.

The vertical member 210 is formed with a through hole 211 through which the locking member 410 passes. The through hole 211 may penetrate the vertical member 210 in the horizontal direction.

In addition, a seat 212 on which the reinforcement 230 is mounted may be formed on the vertical member 210. The seating table 212 may be provided with an a-shaped angle and may be coupled to the vertical member 210. The mounting table 212 and the vertical member 210 may be coupled by welding. The mounting table 212 may be coupled to the vertical member 210 at a point higher than the second board support 220.

The seat 212 may not be formed on the vertical member 210. If the mounting table 212 is not formed, the second support member 200 supports the second foam F2 from the side only by the second knurled support 220.

3 to 6, the second plate support 220 is provided as a square pipe (or circular pipe) to support the second plate F2A from the side. The second knurled support 220 supports the second knurled F2A in a state in which the longitudinal direction is substantially parallel to the horizontal direction.

The second board support 220 has a shape extending laterally from the vertical member 210. One end of the second board support 220 is coupled to the side surface of the vertical member 210. The second board support 220 and the vertical member 210 may be coupled by welding.

When the second support member 200 supports the second board F2A from the side, that is, when the side of the other end of the second board support 220 is in contact with the side of the second board F2A, the vertical The member 210 has a longitudinal direction substantially parallel to the vertical direction.

5 and 6, the reinforcing bar 230 is provided with a square pipe and supports the second profile F2B from the side. The reinforcing bar 230 is interposed between the vertical member 210 and the second profile F2B in a state seated on the mounting table 212. The reinforcing bar 230 supports the second profile F2B from the side while the second board support 220 supports the second board F2A from the side.

In general, a plurality of beam brackets for beam construction are provided to simultaneously support the formwork. The reinforcing bar 230 is provided with a long square pipe in the horizontal direction and is simultaneously seated on the plurality of mounting tables 212.

Therefore, the plurality of beams for beam construction 10 is supported by evenly distributing the side pressure of the formwork 1 through the reinforcing bar 230. In FIG. 6, the upward horizontal arrow indicates the lateral pressure of the concrete (C) acting on the reinforcing bar 230.

7 is a perspective view of a beam bracket for beam construction according to another embodiment of the present invention, and FIG. 8 is a cross-sectional view showing a state of use of the beam bracket for beam construction of FIG. 7.

7 and 8, the second support member 200 may not be provided with a seat 212 and a second board support 220. When the seating table 212 and the second knurled support 220 are not formed on the second support member 200, the vertical member 210 directly adheres to and supports the second profile F2B. That is, the second support member 200 supports the second profile F2B from the side only by the vertical member 210.

3 to 6, the third support member 300 is configured to suppress the rotation and flow of the second support member 200 by the side pressure of the concrete (C), and is provided with a square pipe.

The third support member 300 is coupled to the vertical member 210 and the horizontal member 110. One end of the third support member 300 is coupled to the lower end side of the vertical member 210. And the lower end of the third support member 300 is coupled to the upper surface of the horizontal member (110).

The third support member 300 reinforces the bonding force between the first support member 100 and the second support member 200. The third support member 300 may be coupled to the vertical member 210 and the horizontal member 110 by welding.

5 and 6, the third support member 300, the engaging member 410 and the first support when the contact means 400 attaches the second support member 200 to the angle (A) side It is interposed between the members 100. The third support member 300 is in close contact with the angle A in a direction facing the side pressure as the second support member 200 approaches the angle A by the contact means 400.

When the lateral pressure of the concrete (C) acts on the second support member 200, a rotational force is applied about the hook portion to the beam bracket 10 for beam construction. At this time, the third support member 300 is further in close contact with the angle (A) by the rotational force.

Therefore, the third support member 300 forms a structure that suppresses the rotation and flow of the second support member 200 by the side pressure of the concrete (C). In FIG. 6, the horizontal downward arrow indicates the lateral pressure of the concrete (C) acting on the second board support 220.

As shown in Figures 5 and 6, the contact means 400 is a configuration for forming a coupling force between the beam bracket 10 and the formwork (1) for beam construction, including a locking member 410 and a pusher 420 Is composed.

The locking member 410 is configured to connect the vertical member 210 and the angle (A), and forms a rod shape in which one end portion is bent. The locking member 410 is caught by the angle A through a bent portion (hereinafter, referred to as'hook portion').

The hook portion is rotatably caught in the locking hole (H). That is, while the hook portion is caught in the locking hole H, the locking member 410 may be rotated by a predetermined angle. In a state in which the hook portion is caught in the locking hole H, the rest of the locking member 410 (hereinafter, referred to as'passing portion') passes through the through hole 211.

The pusher 420 is configured to push the second support member 200 toward the angle (A), and is screwed to the passage portion from the opposite side to the angle (A). The pusher 420 may be provided with a female screw with a handle. Male threads may be formed on the outer surface of the passage part.

As shown in FIG. 5, when installing the beam bracket 10 for beam construction, the operator first fastens the hook portion to the locking hole H. And the operator inserts the passage part into the through hole 211 (with the first board support 120 positioned under the first board F1A).

Then, the operator screwed the pusher 420 to the passage portion from the opposite side to the angle (A). After that, the operator turns the handle of the pusher 420. The pusher 420 pushes the vertical member 210 toward the angle (A) in the process of being screwed into the passage part.

The operator strikes the handle of the pusher 420 several times with a hammer and attaches the vertical member 210 to the angle (A) as much as possible. At this time, the closer the vertical member 210 is to the angle A by the contact means 400, the second knurled support 220 is in close contact with the second knurled F2A, and the first knurled support 120 is It is in close contact with the first board F1A.

And the upper surface of the horizontal member 110 is in close contact with the lower end of the first angle (A). In addition, in this process, the third support member 300 is in close contact with the angle A in a direction facing the side pressure. Therefore, the beam bracket 10 and the formwork 1 for the bore construction form a strong bonding force.

This is because in a state in which the locking member 410 is rotatably locked to the angle (A), the pusher 420 moves the vertical member 210 toward the angle (A) while moving along the longitudinal direction of the locking member 410 . That is, the contact means 400 simultaneously forms a horizontal and vertical coupling force between the beam bracket 10 and the formwork 1 for beam construction.

As shown in FIG. 6, when the reinforcing rod 230 is mounted on the mounting table 212, the reinforcing rod 230 is in close contact with the second profile F2B in a direction facing the side pressure.

Therefore, the beam bracket 10 and the formwork (1) for beam construction support the load of the concrete (C) at two points supporting the first board (F1A) and the angle (A), and reduce the lateral pressure of the concrete (C). 2 It is supported at two points supporting the board F2A and the second profile F2B. In FIG. 6, the vertical arrow indicates a load of concrete (C) acting on the first board support 120.

When the lateral pressure of the concrete (C) acts on the second support member 200 after the installation of the borehole bracket 10, a rotational force is applied to the borehole bracket 10 about the hook portion.

The first support member 100 is further in close contact with the board of the first foam (F1) in a direction opposite to the load direction of the concrete (C) by the rotational force described above. Accordingly, a structure in which the rotation of the beam bracket 10 for beam construction by the side pressure of the concrete (C) is firmly blocked by the load of the concrete (C) is formed.

According to the present invention, as the second support member gets closer to the angle by the contact means, the second support member is in close contact with the knurled of the second foam, and the first support member is in close contact with the knurled and angle of the first foam, It is possible to provide a beam bracket for beam construction that is made to directly support the board of a formwork using an angle to form a strong support for the load and side pressure of concrete.

In the above, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have. Accordingly, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should be said to belong to the claims of the present invention.

10,20: Bow bracket
100: first support member 200: second support member
110: horizontal member 210: vertical member
111: coupling part 211: through hole
S: support pipe 212: mounting table
120: 1st board support 220: 2nd board support
300: third support member 230: reinforcement
400: adhesion means
410: locking member
420: pusher
1: formwork
C: concrete
F1: first form
F1A: 1st board
F1B: first profile
F2: 2nd form
F2A: 2nd board
F2B: 2nd profile
H: locking hole
A: Angle

Claims (6)

As a beam bracket for beam construction supporting a first foam forming a floor of the injected concrete and a second foam connected to the first foam at an angle to form a wall of the concrete,
A first support member supporting the knurled and the angle of the first foam from below;
A second support member coupled to the first support member and supporting the board of the second foam from the side; And
And a contact means for attaching the second support member toward the angle,
As the second support member gets closer to the angle by the contact means, the second support member is in close contact with the board of the second foam, and the first support member is attached to the null and the angle A beam bracket for beam construction, characterized in that it adheres closely. The method of claim 1,
The contact means,
A locking member rotatably caught on the angle and passing through the second support member; And
It is screwed to the locking member at the opposite side of the angle, and includes a pusher for pushing the second support member toward the angle,
When the lateral pressure of the concrete acts on the second support member, the first support member is in close contact with the board of the first foam in a direction opposite to the load direction of the concrete. The method of claim 2,
A third support member coupled to the second support member and interposed between the locking member and the first support member,
As the second support member is closer to the angle, the third support member is in close contact with the angle. The method of claim 1,
The first support member,
A horizontal member coupled to the second support member and supporting the angle from below; And
And a first knurling support extending upward from the horizontal member and supporting the knurling of the first foam from below. The method of claim 2,
The second support member,
A vertical member coupled to the first support member and forming a passage hole through which the locking member passes; And
And a second knurling support extending laterally from the vertical member and supporting the knurled of the second foam from the side. The method of claim 5,
The second support member,
It is interposed between the vertical member and the profile of the second foam, and includes a reinforcing rod for supporting the profile of the second foam from the side,
The vertical member, the beam bracket for boscheong characterized in that the reinforcing bar is formed to be seated.

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