KR101127243B1 - Truss of lightweight and long span - Google Patents

Abstract

PURPOSE: A weight lighted prefabricated steel frame structure is provided to reduce costs for a construction and weight of a structure because a thickness of a beam is reduced by forming a span of the upper truss structure shorter than the lower truss structure. CONSTITUTION: A weight lighted prefabricated steel frame structure comprises a main beam unit(20) and a sub beam unit(30). The main beam is arranged as a truss structure to primarily decentralize a loading force(P) added from the upper part. The sub beam is extended as the truss structure in the lower part of the main beam unit, thereby being tensioned or compressed. The sub beam unit secondarily decentralizes the loading force. A traverse direction span of the main beam unit is formed shorter than a traverse direction of the sub beam unit.

Description

Long span lightweight steel structure for assembly {TRUSS OF LIGHTWEIGHT AND LONG SPAN}

The present invention relates to a lightweight steel frame structure for assembling a long span, and more particularly, a beam forming an upper truss by forming a section of an upper truss structure shorter than a section of a lower truss structure among truss structures arranged in a double layer. It is possible to reduce the thickness of the installation cost and to reduce the weight of the structure relates to a lightweight steel structure for the assembly of the long span.

In general, the truss is a type of structure that is installed in a large space such as a bridge or a roof. Arch type utilizing stone characteristics, suspension type and beam type using high tensile strength of steel are mainly used. It is divided into roof truss, parquet truss and strut truss.

The roof truss is designed to protect the interior from natural outdoor conditions such as rain, snow, and wind. The roof material that is bound to the truss has various kinds of lightweight materials such as membrane, petrochemical, and fiberglass products, and has excellent lightability. It is a required situation.

In particular, the steel pipe truss is excellent in structural as well as aesthetic aspect, so it is widely used in buildings with long spans and exposed structures.

Long span trusses have been proposed in Korean Patent Publication No. 10-2006-0034173.

Truss manufactured by welding existing steel has a structural weakness due to the bending of the truss beam in the long span (long span truss). Therefore, the long span truss has a problem that the manufacturing cost increases because the internal stress is used in a large diameter to minimize the bending. Therefore, there is a need for improvement.

The present invention has been made to improve the above problems, the thickness of the beam forming the upper truss can be reduced by forming the interval of the upper truss structure shorter than the interval of the lower truss structure of the truss structure arranged in multiple layers. The purpose of the present invention is to provide a lightweight steel structure for assembly of long spans to reduce installation costs and to reduce the load on the structure.

In addition, the present invention can reduce the support distance of the purlin (furlin) installed on the upper side of the upper truss structure by shortening the interval of the upper truss structure, thereby reducing the length of the long span lightweight steel assembly for assembly The purpose is to provide a structure.

The lightweight steel frame assembly for assembly of the long span according to the present invention includes: a main beam portion arranged in a truss structure for distributing a load force applied from an upper portion thereof, and extending in a truss structure under the main beam portion; And a sub-beam portion for distributing the load force secondaryly, wherein the transverse interval of the main beam portion is shorter than the transverse interval of the sub-beam portion.

The main beam portion, the main top chord directly receiving the load force, the main bottom chord arranged side by side with the main top chord, one side is connected to the main top chord to distribute the load force and the other side is the main bottom chord A main right facing material arranged to be inclined at the same angle so as to be spaced apart at a predetermined interval along the axial direction of the main upper current, and a main right facing material connecting the main right facing material adjacent to each other by being inclined symmetrically with the main right facing material Include.

The sub beam part may be disposed along the axial direction of the main lower chord so as to be spaced apart at a predetermined interval to support the main beam part, and the sub yarn arranged in parallel with the main lower chord, and to connect a lower side of the sub yarn. Contains the lower chord.

The sub yarns are inclined to be in line with the corresponding main right-side yarn and are connected to the sub-lower chord, and the sub-lower yarns inclined to be in line with the corresponding main right-side yarn. It includes a sub-right facing material extending from the yarn and connected to the main lower chord.

It is preferable that the length of the main right side facing material is shorter than the length of the sub right side facing material, and the length of the main right side facing material is shorter than the length of the sub right side facing material.

The main upper chord and the main lower chord are thinner than the thickness of the sub lower chord, and the main lower right yarn and the main right upward material are thinner than the thicknesses of the sub right downward direction material and the sub right upward direction material.

As described above, the lightweight steel structure for the assembly of the long span according to the present invention, unlike the prior art, forming the upper truss of the truss structure arranged in a double layer than the lower truss of the truss structure arranged in a double layer to form an upper truss The thickness of the beam can be reduced, thereby reducing installation costs and reducing the load on the structure.

In addition, the present invention can reduce the support distance of the purlin (purlin) installed on the upper side of the upper truss structure by shortening the interval of the upper truss structure, thereby reducing the quantity of the purlin.

1 is a perspective view of a steel structure according to an embodiment of the present invention.
2 is a side view of the steel structure according to an embodiment of the present invention.
3 is an enlarged side view of a part of the steel structure according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the lightweight steel frame assembly of the long span according to the present invention. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. 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.

1 is a perspective view of a steel structure according to an embodiment of the present invention, Figure 2 is a side view of the steel structure according to an embodiment of the present invention, Figure 3 is a side portion of the steel structure according to an embodiment of the present invention It is an enlarged view.

1 to 3, the steel structure 10 according to an embodiment of the present invention is applied to the long span of the large space structure, characterized in that to reduce the weight (Dead Load) to reduce the weight do.

In other words, the steel frame structure 10 according to an embodiment of the present invention includes a main beam part 20 located at an upper side and a sub beam part 30 located at a lower side, formed of a multi-layered truss structure.

Here, the truss structure refers to a structure that supports the load by weaving steel or wood in a triangular net shape. It is often used as a structure that spans large spaces such as bridges or roofs. The reason why the truss is composed of a triangular unit space is that the triangular configuration can maintain a stable form without deformation even more easily in the rectangular space even if the connection point is the rotating end.

In particular, the main beam unit 20 is arranged in a truss structure to primarily distribute the load force P applied from the top. On the upper side of the main beam portion 20, a single layer or multiple layers of purlin (not shown) are stacked. Thus, the main beam portion 20 is subjected to a load force P pressed over the entire upper side. Furin is used to prevent buckling (bending) of the components 22, 24, 26, 28 constituting the main beam portion 20 and the components 32, 34, 36, 38 constituting the sub beam portion 30. It refers to a member that fixes the horizontal member and the vertical member, or the horizontal member and the vertical member diagonally.

In addition, the sub-beam portion 30 extends in the truss structure under the main beam portion 20 to be tensioned or compressed and serves to secondaryly distribute the load force (P).

On the other hand, the main beam portion 20 is composed of the main upper choke 22, the main lower chord 24, the main right downward yarn material 26 and the main right upward yarn material 28.

The sub-beam section 30 includes a sub yarn 32 and a sub river chord 34 including a sub right downward reflective material 36 and a sub right upward reflective material 38.

At this time, in order to reduce the self-load of the steel structure 10, it is preferable to thin the thickness of at least one of the main beam portion 20 and the sub-beam portion 30 compared to the existing.

In other words, the main upper chord 22, the main lower chord 24, the main right-side facing material 26 and the main right-side facing material 28 constituting the main beam portion 20 may be formed thinner than the conventional.

In addition, the sub yarn 32 and the sub lower chord 34 including the sub right direction directing member 36 and the sub right direction directing member 38 constituting the sub beam part 30 may be as thin as the main upper current 22. have.

Here, when the main upper choke 22, the main lower chord 24, the main right direction facing material 26 and the main right direction facing material 28 becomes thinner, the internal stress becomes smaller and can be easily bent.

Similarly, when the sub yarn material 32 and the sub river chord 34 including the sub right direction yarn 36 and the sub right direction yarn 38 become thinner, the internal stress becomes smaller and can be easily bent.

Thus, the main upper chord 22, the main lower chord 24, the main right side facing material 26 and the main right side facing material 28 can be made of a relatively short length, it is preferably formed of the same diameter.

Similarly, the sub yarn 32 and the sub lower chord 34 including the sub right direction facing material 36 and the sub right direction facing material 38 may have a relatively short length and are preferably formed with the same diameter.

In this case, the sub yarn 32 and the sub lower chord 34 including the sub right direction facing material 36 and the sub right direction facing material 38 are formed of the components 22, 24, 26, of the main beam part 20, 20. If it is formed as short as 28), the number of parts to be assembled is increased to increase the assembly cost.

Accordingly, the components 22, 24, 26, 28 of the main beam portion 20 that are primarily subjected to the load force P are thinner than the components 32, 34, 36, 38 of the sub-beam portion 30. It is preferable to form short.

As a result, the transverse span of the main beam unit 20 is made shorter than the transverse span of the sub-beam unit 30. That is, the length of the main lower chord 22 is formed shorter than the length of the sub lower chord 34.

In this case, as described above, the main beam unit 20 includes a main upper chord 22, a main lower chord 24, a main right downward directional material 26 and a main right upward directional material 28.

The main upper chord 22 is subjected to an even load force P as a whole by the furin raised on the upper side. In addition, although not shown in figure, the main phase chord 22 is arranged in multiple numbers on the same plane.

The main lower chord 24 is arranged side by side with a predetermined clearance in the vertical direction with the main upper chord 22. The main lower chord 24 may be provided to correspond one-to-one with the main top chord 22 or may be provided in a different number from the main top chord 22.

In addition, the main right-side facing material 26 serves to evenly distribute the load force (P) applied directly to the main upper chord 22.

The main right facing yarn 26 is connected to the main lower chord 22 on one side and the main lower chord 24 on the other side. At this time, the main right downward yarn material 26 is formed to be inclined rightward downward from one side to the other side along the axial direction of the main upper chord 22, and spaced apart along a axial direction of the main upper chord 22. It is arranged and provided to be inclined at the same angle.

In addition, the main right upward inclined material 28 is inclined in a symmetrical direction to the main right downward inclined material 26, that is, in a right upward direction, and serves to connect the neighboring main right downward inclined material 26. That is, the lower side of the main right upward facing material 28 is connected to the lower side of the main right facing yarn 26 and the main lower chord 24 of one of the neighboring main right facing yarns 26, and the upper side of the main right facing yarn 28 is the other side. It is connected to the main lower right direction of the material 26 and the main phase current 22.

Accordingly, the main right downward yarn 26 and the main right upward yarn 28 are continuously arranged in a zigzag shape between the main upper chord 22 and the main lower chord 24. Thus, the main right downward directional material 26 and the main right upward directional material 28 distribute the load force P applied to the main upper chord 22 evenly while being supported by the main lower chord 24.

On the other hand, the sub-beam section 30 includes the sub yarn 32 and the sub lower chord 34 as described above.

The sub lower chord 34 is located below the main lower chord 24, and is arranged in parallel with the main lower chord 24.

In addition, the sub yarn 32 is disposed along the axial direction of the main lower chord 24 to be spaced apart by a predetermined interval and is compressed or stretched against the load force P to support the main beam part 20. That is, the sub yarn 32 is disposed discontinuously between the main lower chord 24 and the sub lower chord 34.

In particular, as described above, the sub yarn material 32 includes a sub right downward yarn material 36 and a sub right upward yarn material 38.

The sub-lower yarn directing material 36 is inclined to be in line with the corresponding main right-side yarn facing material 26 and connected to the sub lower chord 34. That is, the sub-lower yarn directing material 36 constituting any one of the sub yarns 32 is inclined in a right downward direction so as to be in line with the corresponding main right-lower yarn material 26. The sub-lower direction facing material 36 is connected to the main lower direction direction material 26 and the main lower chord 24, and the lower side thereof is connected to the sub lower chord 34.

In addition, the sub-right facing material 38 is inclined in a straight line or close to a straight line with the corresponding main right facing material 28 and is connected to the sub right facing material 38. That is, the sub-right facing material 38 constituting any one of the sub yarns 32 is disposed to be inclined in a right upward direction so as to be in a straight line or a straight line with the corresponding main right facing material 28. The upper right side facing material 38 is connected to the main right side upward facing material 28 and the main lower chord 24, and the lower side is connected to the lower right side facing material 36 and the sub lower chord 34.

In this case, at least one main body may be disposed between the main right directing yarn 26 disposed to be in a straight line or close to the sub-right directivity yarns 36 and the main right upward facing material 28 disposed to be in a straight line or straight line with the sub right upward directing material 38. The right upper side inclined material 28 and one or more main right side inclined material 26 are disposed.

This is because the length of the main right facing material 26 is shorter than the length of the sub right facing material 36, and the length of the main right facing material 28 is shorter than the length of the sub right facing material 38.

In particular, the sub-beam unit 30 alternately forms a truss structure of a triangular trajectory and a truss structure of a rhombus trajectory along the axial direction of the sub lower chord 34.

That is, the sub lower chord 34, the sub right downward direction material 36, and the sub right upper direction direction material 38 which comprise one sub beam part 30 are comprised by the locus of an inverted triangle shape.

Then, the sub lower chord 34, the sub lower right direction material 36 and the sub right upper direction material 38 constituting the neighboring sub beam part 30 are formed in a locus of an inverted triangle shape.

In addition, a truss structure of a rhombus trajectory surrounded by the main lower chord 24, the sub-right top facing material 38, the sub-bottom head 34, and the sub-lower right facing material 36 is provided between a pair of neighboring sub-beam sections 30. do.

However, the main right side upwards 28 of the main beam portion 20 of the main beam portion 20 disposed in a straight line to the sub-right direction facing material 38 and the main right side down direction of the main beam portion 20 of the main beam portion 20 disposed in a straight line. As a truss structure is formed between the sub-beam portions 30 of the inverted triangular shape trajectory, the main beam portion 20 and the sub-beam portion 30 are formed. Steel structure 10 is a stable truss structure as a whole.

Particularly, one of the two sides of the triangular trajectory of a large area is connected such that the main right top facing material 28 and the sub right top facing material 38 are arranged in a straight line or close to a straight line, and the main right facing material 28 has a load force ( Compressed by P), and the sub-right directivity material 38 is tensioned.

Similarly, the main right side facing material 26 and the sub right side facing material 36 are connected to the other side of both sides of a triangular trajectory of a large area in a straight line, and the main right side facing material 26 is connected to a load force P. Is compressed, and the sub-lower facing yarn 36 is tensioned.

Thus, by simultaneously realizing compression and tension in a state of being inclined or close to a straight line across the main beam portion 20 and the sub-beam portion 30, the steel structure 10 can reduce the degree of buckling.

In addition, the length L1 of each of the main upper chords 22 connected to each other is the same as the length of each of the main lower chords 24 connected to each other, and the length of each of the main right-side facing material 26 and the main right-side facing material 28. Is done the same as

In addition, the length (L2) of each of the sub-lower direction facing material 36 is made the same as the length of each of the sub-right direction facing material (38).

In addition, the length L1 of the main upper chord 22 is shorter than the length L2 of the sub-lower direction facing material 36.

In addition, the length L3 of each of the sub lower chords 34 connected to each other is spaced apart from each other by the sub-beam portions 30 so as to be longer than the length L2 of the sub right lower direction yarn 36.

Accordingly, the main beam directing member 26 and the main upper directing member 28 along the axial direction of the main beam portion 20 along the axial direction of the main upper chord 22 and the main lower chord 24. The sub-right facing material 38 and the sub-right facing material 36 are located along the lateral interval of the sub beam part 30, that is, the axial direction of the main lower chord 24 and the sub lower chord 34. It becomes shorter than the space | interval (L3) between the connection parts of.

In other words, the lengths of the main right facing material 26 and the main right facing material 28 and the main right facing material 26 and the main right facing material 24, respectively, are respectively represented by the sub right facing material 36, the sub right facing material 38, and the sub. It is formed shorter than the length of the lower chord (34).

Thus, even if the main upper chord 22 and the main lower chord 24 each have a short length of the main right facing material 26 and the main right facing material 28, the main beam part 20 is applied to the existing load force P. I can stand it.

For this reason, the thickness T1 of the main upper chord 22 and the main lower chord 24 is thinner than the thickness T2 of the sub lower chord 34.

At this time, the thickness of the main upper chord 22 may be formed to be thicker than the thickness of the main lower chord 24, but the thickness of the main upper chord 22 and the main lower chord 24 are both sub-low chord (34) It is formed thinner than the thickness T2.

In addition, the thickness T1 of the main right side facing material 26 and the main right side facing material 28 is thinner than the thickness T2 of the sub right side facing material 36 and the sub right side facing material 38.

Therefore, the load of the steel structure 10 is reduced. And since the space | interval L1 of the main image pole 22 becomes short, the magnitude | size (volume) of the furlin provided in the upper side of the main beam part 20 can be reduced.

On the other hand, each of the main upper choke 22, the main lower chord 24, respectively, the main right facing material 26, the main right facing material 28, the sub right facing material 36, the sub right facing material 38 and the sub lower chord ( 34) Each is connected in various ways such as a ball joint (2).

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. I will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: steel structure 20: main beam portion
22: Main High Present 24: Main High Present
26: Main Uhyang Saengjae 28: Main Uhyang Saengjae
30: sub beam part 32: sub material
34: Subha present 36: Sub right downward direction
38: Sub idol scent

Claims (5)

A main beam part arranged in a truss structure to firstly distribute a load force applied from an upper part; And
A sub beam portion extending in a truss structure below the main beam portion to secondaryly distribute the load force;
The steel frame for light weight assembly of a long span, characterized in that the transverse section of the main beam section is shorter than the transverse section of the sub-beam section.
The method of claim 1, wherein the main beam portion,
Main phase current directly receiving load;
A main lower chord arranged side by side with the main upper chord;
A main right side facing material disposed to be inclined at the same angle so that one side is connected to the main upper chord and the other side is connected to the main lower chord to be spaced apart along a axial direction of the main upper chord to distribute the load force; And
Lightweight steel frame assembly for assembly of the long span, characterized in that it comprises a main right top facing material consisting of a slope symmetrical with the main right facing yarn connecting the main right facing yarn.
The method of claim 2,
The sub beam part may include: a sub material that is spaced apart by a predetermined interval along the axial direction of the main lower chord to support the main beam part; And
It is arranged side by side with the main lower chord, and includes a sub lower chord connecting the lower side of the sub yarn,
The sub yarns may include: a sub right downward yarn inclined to be in line with a corresponding main right downward yarn and connected to the sub lower chord; And
Light-weighted steel frame for assembly of the long span, characterized in that it includes a sub-right upward facing material extending from the sub-right facing yarn connected to the sub lower chord inclined to be in line with the corresponding main right upward facing material. structure.
The method of claim 3, wherein
The length of the main right-side yarn is shorter than the length of the sub-right side yarn;
The steel frame structure for light weight assembly of the long span, characterized in that the length of the main right top facing material is formed shorter than the length of the sub right top facing material.
The method of claim 3, wherein
The main upper chord and the main lower chord are thinner than the thickness of the sub lower chord;
The steel frame structure for light weight assembly of the long span, characterized in that the main right-side down yarn and the main right-side down yarn is formed to be thinner than the thickness of the sub-right side facing down material and the sub-right upward facing material.

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