KR101923547B1 - Device for supporting architecture structure - Google Patents

Abstract

The invention relates to a support device for civil engineering and construction. The present invention relates to a supporting structure for civil engineering and construction, comprising: a first supporting portion for forming a flange to be supported by a structure; a second supporting portion coupled to the first supporting portion to form a flange to be supported by the structure; And an inner curvature portion formed on a bottom surface of the receiving portion of the second support portion so that the outer curvature portion is brought into contact with the outer curvature portion and a load applied to the outer curvature portion and the inner curvature portion, And a load distributing unit for distributing the load.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

More particularly, the present invention relates to a supporting device for civil engineering and construction, and more particularly, to a supporting device for civil engineering and construction, And to prevent damage caused by the widthwise rotational moment applied to the support portion and the second support portion, respectively.

Generally, the supporting devices for civil engineering and construction structures are designed to support the load of concrete during concrete curing at the construction sites such as underground roads, subways, underground runners of apartment buildings, etc., before or at the time of concrete curing This is an easy civil engineering and construction equipment.

Particularly, the supporting devices for civil engineering and constructional structures are designed to withstand high loads and to absorb vibration loads. BACKGROUND ART [0002] Conventional civil and architectural structure supporting apparatuses mainly include an upper supporting portion and a lower supporting portion.

The upper support portion is pivotally coupled at the lower support portion.

A hinge hole is formed through the lower end of the upper support portion. The upper support portion is formed with a connecting piece having an elongated hole communicating with the hinge hole. The hinge hole and the long hole are hingedly coupled to each other by a hinge shaft.

The lower end portion of the upper support portion and the inner surface portion of the lower support portion come into contact with each other and the load acts in the vertical direction while maintaining a certain angle.

However, in the conventional support structure for civil engineering and construction structures, the high load of the upper structure coupled to the upper support portion is concentrated and transferred to the inner surface of the lower support portion via the lower end of the upper support portion in a state where the lower end of the upper support portion and the inner surface of the lower support portion are in contact with each other When the torsion moment or the widthwise rotation moment is applied to the upper support portion, there is a problem that the connection portion between the upper support portion and the lower support portion is broken.

Therefore, there is a need to improve this.

As related background technology, Korean Patent Registration No. 0962553 (Jun. 3, 2010, entitled "Civil and Architectural Support Device") is available.

The present invention has been made in view of the above-described need, and it is an object of the present invention to provide a load distributing unit for supporting and distributing a load applied to an outer curvature portion of a first supporting portion and a curvature portion of a second supporting portion, And it is an object of the present invention to provide a support device for civil engineering and construction which can prevent damage due to a widthwise rotation moment and a torsional moment applied to a support portion.

According to an aspect of the present invention, there is provided a support device for civil engineering and construction, comprising: a first support part forming a flange to be supported by a structure; A second support portion coupled to the first support portion and forming a flange to be supported by the structure; An outer curvature portion formed at an end of the first support portion; An inner curvature portion formed on a bottom surface of the receiving portion of the second support portion such that the outer curvature portion is in contact with the inner curvature portion; And a load dispersing unit that is provided to be able to contact the first support unit and the second support unit and disperses a load applied to the outer and inner curvature parts.

The load distribution unit may include: a dispersion outside curvature portion formed at an end of the second support portion; And a dispersion internal curvature portion formed around the outer curvature portion in the first support portion so as to be in contact with the outer dispersion curvature portion.

The outer dispersed curvature portion may include a first dispersed outer curvature portion formed at one side of the receiving portion to disperse and support a load applied to the inner curvature portion and the outer curvature portion in one direction; And a second dispersed outer curvature portion formed on the other side of the receiving portion to disperse and support a load applied to the inner curvature portion and the outer curvature portion in the other direction.

The curvature portion may include a first dispersion internal curvature portion formed on one side of the outer curvature portion of the first support portion so as to be in contact with the first dispersion outer curvature portion; And a second dispersion intracavity curved portion formed on the other side of the outer curvature portion of the first support portion to be in contact with the first dispersion outer curvature portion.

The curvature portion is formed in a semicircular shape, and a reinforcing rib is formed on one side of the curvature portion.

In addition, a position restricting portion is formed around one side of the curvature-of-dispersion portion, and the position restricting portion is caught by the position restricting groove portion formed on one side of the dispersed outer curvature portion. Therefore, Thereby limiting the rotation.

The flange of the second support part may have a through hole into which a bolt member is inserted to be fastened to the structure, and a thickness expansion reinforcing part having a thickness larger than the thickness of the flange is provided at an edge of the through hole.

Further, the present invention is characterized in that it includes a pivotal mounting portion that rotatably supports the first support portion and the second support portion.

In addition, the pivotal mounting portion may include: a rotating hole formed in the receiving portion of the second supporting portion; An insertion portion connected from the periphery of the second support portion to the rotation hole; A rotation shaft integrally formed on the first support portion and installed in the rotation hole through the insertion portion; And an opening / closing part formed around the second supporting part to open / close the insertion part to prevent separation of the rotation shaft.

The opening / closing portion may include a cap member inserted into the insertion portion of the second support portion to block the insertion portion; And a coupling member which is provided on a side surface of the cap member and allows the cap member to be coupled to the second support portion.

The load applied to the outer curvature portion of the first supporting portion and the inner curvature portion of the second supporting portion is supported and dispersed by the load dispersing portion so that the first supporting portion and the second supporting portion And can be prevented from being damaged by the respective widthwise rotation moment or torsional moment applied thereto.

Further, according to the present invention, since the protruding position of the outer curvature portion and the recessed position of the inner curvature portion are formed in opposite directions to each other, the protruding position of the dispersed outer core portion and the recessed position of the inner curvature portion of dispersion are opposite to each other, .

Further, the present invention is provided with a thickened reinforcing portion that increases the thickness of the through hole of the flange, so that the through hole can be prevented from being damaged by the concentrated load of the fastening member.

1 is an exploded perspective view of a supporting device for civil engineering and construction according to an embodiment of the present invention.
2 is an assembled perspective view of a support device for civil engineering and construction according to an embodiment of the present invention.
3 is a cross-sectional view of a supporting structure for civil engineering and construction according to an embodiment of the present invention.
4 is a sectional view of the assembled state of Fig.
5 is a side view of an operation state of a civil engineering and construction support apparatus according to an embodiment of the present invention.
FIG. 6 is a sectional view of an assembled state center portion of a supporting apparatus for civil engineering and construction according to an embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a supporting apparatus for civil engineering and construction according to an embodiment of the present invention will be described with reference to the accompanying drawings.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is an exploded perspective view of a supporting apparatus for civil engineering and construction according to an embodiment of the present invention, FIG. 2 is an assembled perspective view of a supporting apparatus for civil engineering and construction according to an embodiment of the present invention, and FIG. FIG. 4 is a sectional view of the assembled state of FIG. 3, FIG. 5 is a side view of the operating state of the neck and building supporting apparatus according to the embodiment of the present invention, and FIG. FIG. 3 is a sectional view of an assembled state center portion of a supporting apparatus for civil engineering and construction according to an embodiment of the present invention.

1 to 6, a supporting device for civil engineering and construction according to an embodiment of the present invention includes a first supporting portion 100, a second supporting portion 200, an outer curvature portion 300, a curvature portion 400 And a load dispersing unit 500.

The first support part 100 is configured to support the flange 110 to be supported by the structure.

The second support portion 200 is configured to be coupled to the first support portion 100 to form the flange 210 to be supported by the structure.

The outer curvature portion 300 is formed at an end portion of the first support portion 100.

The inner curvature portion 400 is formed on the bottom surface of the receiving portion of the second support portion 200 so that the outer curvature portion 300 is in contact with the curvature portion.

The load dispersing unit 500 is configured to be able to contact the first supporting unit 100 and the second supporting unit 200 and is configured to disperse the load applied to the outer and inner curvature portions 300 and 400.

The load distributor 500 is designed so that when the flange 110 of the first support part 100 is subjected to a load in the direction of the width, only the outer and inner curvature parts 300 and 400 have a widthwise load, So that it can support the load on both sides.

That is, when the flange 110 of the first support part 100 is subjected to a widthwise load, both sides of the receiving part 205 of the second support part 200 may be damaged by excessive contact of the first support part 100 So that the load dispersing unit 500 supports the first and second support parts 100 and 200 to prevent the connection parts between the first support part 100 and the second support part 200 from being damaged.

The load distributor 500 includes a dispersion outer curvature portion 510 formed at the end of the second support portion 200 and a curvature portion 500 at the outer circumferential portion 300 of the first support portion 100, And a distributed curvature portion 540 formed around the curved portion 540. [

The out-of-curvature curvature portion 510 is formed on one side surface of the accommodating portion 205 and has a first dispersed outer curvature < RTI ID = 0.0 > And a second dispersed outer curvature portion 530 formed on the other side of the receiving portion 205 for dispersing and supporting a load applied to the inner curvature portion 400 and the outer curvature portion 300 in the other width direction, ).

The first dispersion outside curvature portion 520 and the second dispersion outside curvature portion 530 are formed to correspond to each other with respect to the accommodation portion 205.

The first dispersion outside curvature portion 520 and the second dispersion outside curvature portion 530 may be formed in an arc shape, in particular, a semicircular protrusion shape.

The first outer dispersion curvature portion 520 and the second dispersion outer radius curvature portion 530 are rotatably contacted with the first dispersion inner curvature portion 550 and the second dispersion inner curvature portion 560 to be described later, 2 eccentric load which can not be supported by the outer and inner curvature portions 200 and 400 when the first supporting portion 100 is rotated with respect to the supporting portion 200, Prevent the building support device from being damaged.

The curved dispersion portion 540 includes a first dispersion internal curvature portion 550 formed on one side of the external curvature portion 300 of the first support portion 100 to be in contact with the first external dispersion curvature portion 520, And a second dispersion curvature portion 560 formed on the other side of the outer curvature portion 300 of the first support portion 100 to be in contact with the first dispersion outer curvature portion 530.

The first dispersion inside curvature portion 550 and the second dispersion inside curvature portion 560 are formed in an arc groove shape so as to have a first dispersion outside curvature portion 520 and a second dispersion outside curvature portion 530 It is possible to be rotated while sufficiently supporting the load even if the widthwise rotational moment or torsional moment of the first support portion 100 is applied to the second support portion 200. [

A reinforcing rib 512 connected to the flange 210 may be formed on one side of the out-of-dispersion curvature portion 510.

The position restricting protrusion 570 may be formed around one side of the curvature portion 540 of the dispersion.

The position restricting protrusion 570 is caught by the position restricting groove portion 580 formed around one side of the dispersed outer curvature portion 510 so that rotation of the second supporter 100 relative to the first supporter 200 can be restricted .

The anti-jamming plane portion 590 may be formed on the other side of the curved dispersion portion 540 to prevent the dispersion outer curvature portion 510 from being caught on entry.

The height of the locking surface 590 may be lower than the height of the position limiting protrusion 570.

The latching preventing surface portion 590 is formed horizontally and flat when the second supporting portion 100 is horizontally laid.

The inclined reinforcing portion 595 may be formed at the edges of the position restricting protrusion 570 and the engaging preventing portion 570 so as to be wider toward the lower side to reinforce the strength.

Since the inclined reinforcing portion 595 is formed to be inclined with increasing width toward the flange 110, the load applied to the first and second dispersed curvature portions 550 and 560 at the first and second dispersed outer curved portions 520 and 530 is wide Because it spreads over the area, it can help to effectively support the load.

Referring to FIG. 4, the widths of the first and second dispersion outer curvature portions 520 and 530 may be formed to be wider than the widths of the first and second dispersion inner curvature portions 550 and 560. The first support part 100 is located on the upper side and the second support part 200 is mainly located on the lower side so that the first support part 100 flows in the width direction in the second support part 200 and the rotation moment or torsion moment The first and second dispersed outer curved portions 520 and 530 located at the lower side accommodate the load ranges of the first and second distributed inner curved portions 550 and 560 located on the upper side, The outer dispersion curved portions 520 and 530 can stably support the loads of the first and second dispersion inner curvature portions 550 and 560. [

The flange 210 of the second support part 200 is formed with a through hole 220 into which a bolt member is inserted to be fastened to the structure.

The thickness of the through-hole 220 may be greater than the thickness of the flange 210.

The upper and lower widths are formed so as to be narrower downward from the upper end to the bottom of the flange 210 so that the load applied from the head or the nut member of the bolt member is directed toward the flange 210 side So that the through hole 220 is prevented from being broken.

And a pivotal mounting part 600 for supporting the first supporting part 100 and the second supporting part 200 in a rotatable manner.

The pivotal mounting part 600 includes a rotation hole 610 formed in the receiving part 205 of the second supporting part 200 and an insertion hole 610 extending from the periphery of the second supporting part 200 to the rotating hole 610. [ A rotation shaft 630 formed integrally with the first support portion 100 and installed in the rotation hole 610 through the insertion portion 620 and an insertion portion 630 formed in the rotation shaft 630 in order to prevent separation of the rotation shaft 630, 620 formed at the periphery of the second support portion 200 to open and close the second support portion 200.

The insertion portion 620 may be inclined from the rotation hole 610 to the circumferential side of the first support portion 100.

The inclusion of the insertion portion 6200 allows the dispersion outer curvature portion 510 and the dispersion inner curvature portion 540 to be stably assembled without colliding with each other.

The opening and closing part 640 includes a cap member 642 inserted into the insertion part 620 of the second support part 200 to block the insertion part 620 and a cap member 642 provided on the side surface of the cap member 642, And a fastening member 644 for allowing the cap member 642 to be engaged in the cap member 200. [

The fastening member 644 is preferably a bolt.

Hereinafter, the operation and effects of the civil and architectural support apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings.

The rotating shaft 630 formed on both sides of the first supporting part 100 is moved through the receiving part 620 of the second supporting part 200 to move the first supporting part 100 and the second supporting part 200, So as to be seated in the rotation hole 610.

After the cap member 642 is inserted into the insertion portion 620, the coupling member 644 is fastened from the outside of the first support portion 200 to fasten the cap member 642 to the insertion portion 620 So that it is possible to prevent the rotation shaft 630 from coming off.

At this time, since the outer curvature portion 300 of the first support portion 100 contacts the inner curvature portion 400 of the second support portion 200, the load can be supported.

Since the first and second curvature portions 550 and 560 formed on the first support portion 100 are respectively in contact with the first and second curvature portions 520 and 530 of the second support portion 200, And the load applied to the inner curvature portion 400 can be dispersed.

Particularly, when the first support portion 100 applies an eccentric load in the width direction with respect to the second support portion 200, the first support portion 100 moves in the right and left directions to move the receiving portion 205 of the second support portion 200 The first and second dispersion internal curvature portions 550 and 560 formed on both sides of the external curvature portion 300 and the first and second dispersion internal curvature portions 550 and 560 formed on both sides of the internal curvature portion 400, It is possible to prevent the first support portion 100 and the second support portion 200 from being damaged by distributing and supporting the eccentric load such as the widthwise rotation moment or the torsional moment in the curved portions 520 and 530. [

Therefore, in the supporting apparatus for civil engineering and construction according to an embodiment of the present invention, since the load applied to the outer curvature portion of the first supporting portion and the inner curvature portion of the second supporting portion is supported and dispersed by the load dispersing portion, And can be prevented from being damaged by the widthwise rotation moment applied to the support portion and the second support portion, respectively.

Further, since the protruding position of the outer curvature portion and the recessing position of the inner curvature portion are formed in opposite directions to each other, the protruding position of the dispersed outer grooved portion and the recessed position of the distributed inner curvature portion can further improve the load distribution and support effect. Further, the present invention is provided with a thickened reinforcing portion that increases the thickness of the through hole of the flange, so that the through hole can be prevented from being damaged by the concentrated load of the fastening member.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

100 -: first support part 110: flange
200: second supporting portion 210: flange
220: Through hole 230: Thickness expansion reinforcing portion
300: Outer curvature part 400: Knuckle curvature part:
500: load dispersion part 510: outer dispersion curvature part
520: first dispersion outside curvature portion 530: second dispersion outside curvature portion
540: dispersion-inside curvature portion 550: first dispersion-inside curvature portion
560: second dispersion intracavity curved portion 570: position restricting projection
580: Position restricting groove portion 590:
595: inclined reinforcing part 500:
610: rotation hole 620: insertion part
630: rotating shaft 640: opening /
642: cap member 544:

Claims (10)

A first support for forming a flange to be supported on the structure; A second support portion coupled to the first support portion and forming a flange to be supported by the structure; An outer curvature portion formed at an end of the first support portion; An inner curvature portion formed on a bottom surface of the receiving portion of the second support portion such that the outer curvature portion is in contact with the inner curvature portion; And a load dispersing unit provided so as to be able to contact with the first and second support units and dispersing a load applied to the outer and inner curvature portions,
The load distribution unit may include: a dispersion outer curvature portion formed at an end of the second support portion; And a dispersion curvature portion formed around the outer curvature portion in the first support portion to be in contact with the outer dispersion curvature portion,
Wherein the out-of-dispersion curvature portion comprises a first distributed outer curvature portion formed on one side surface of the receiving portion to disperse and support a load applied to the inner curvature portion and the outer curvature portion in one direction; And a second distributed outer curvature portion formed on the other side surface of the receiving portion to disperse and support a load applied to the inner curvature portion and the outer curvature portion in the other direction,
Wherein the curvature portion of the dispersion includes a first dispersion intracavity portion formed on one side of the outer curvature portion of the first support portion so as to be in contact with the first dispersion outer curvature portion; And a second dispersion intracavity curvature portion formed on the other side of the outer curvature portion of the first support portion to be in contact with the first dispersion outer curvature portion,
Wherein the first dispersion inside curvature portion and the second dispersion inside curvature portion are formed in an arc groove shape so as to contact the first dispersion outside curvature portion in a semicircular projection shape and the second dispersion outside curvature portion, In addition,
The width of the first and second dispersion outside curvature portions is formed wider than the widths of the first and second dispersion inside curvature portions so that the first support portion flows in the width direction in the second support portion and the rotational moment and torsional moment Wherein when the load is applied to the lower side, the first and second dispersed inside curvature portions located on the lower side are accommodated within the load ranges of the first and second distributed inside curvature portions, thereby stably supporting the load. Supporting devices for construction.
delete delete delete The method according to claim 1,
The out-of-dispersion curvature portion is formed in a semi-circular shape,
And a reinforcing rib that is connected to a flange is formed on one side of the curvature portion outside the dispersed portion.
The method according to claim 1,
A position restricting portion is formed on one side of the curvature portion of the dispersion,
Since the positioning hinge portion is caught by the position restricting groove portion formed on one side of the outer dispersion curvature portion,
And restricting rotation of the second support relative to the first support.
The method according to claim 1,
A through hole through which a bolt member is inserted to be fastened to the structure is formed in the flange of the second support portion,
Wherein the through-hole has a thickness enlarged reinforcing portion having a thickness greater than the thickness of the flange.
8. The method according to any one of claims 5 to 7,
And a pivotal mounting portion for supporting the first supporting portion and the second supporting portion so as to be rotatable relative to each other.
9. The method of claim 8,
The rotation-
A rotation hole formed in the receiving portion of the second support portion;
An insertion portion connected from the periphery of the second support portion to the rotation hole;
A rotation shaft integrally formed on the first support portion and installed in the rotation hole through the insertion portion; And
And an opening / closing part formed around the second supporting part to open / close the insertion part to prevent separation of the rotation shaft
Including civil engineering and architectural support devices.
10. The method of claim 9,
The opening /
A cap member inserted into the insertion portion of the second support portion to block the insertion portion; And
A coupling member provided on a side surface of the cap member and adapted to couple the cap member to the second support portion;
Wherein the support structure comprises:

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