KR20210141075A - Sectional height variable type girders comprising anchorblock assembly - Google Patents

Abstract

Disclosed is a sectional height variable-type girder comprising an anchor block assembly. According to an aspect of the present invention, a sectional height variable-type girder comprising an anchor block assembly comprises: a girder part; a plate bar disposed under the girder part and extending in a longitudinal direction of the girder part; a pair of anchor block assemblies for fixing both ends of the plate bar to the girder part; and a pair of inclined members having one end coupled to the plate bar between the pair of anchor block assemblies, and the other end coupled to the anchor block assembly by extending diagonally upward. A slot hole extending in a longitudinal direction of the girder part is formed in a lower flange of the girder part. The anchor block assembly includes: an anchor block seated on the plate bar, and having an upper portion coupled to the other end of the inclined member; a bolt having a head part seated on the lower flange, and a threaded part extending downward from the head part and penetrating the anchor block and the plate bar through the slot hole; and a nut screwed to a lower end of the threaded part. The plate bar is fixed to the girder part by frictional resistance between the head part and the lower flange in a state where pre-tension is applied.

Description

SECTIONAL HEIGHT VARIABLE TYPE GIRDERS COMPRISING ANCHORBLOCK ASSEMBLY

The present invention relates to a type-height variable girder comprising an anchor block assembly.

A girder is an upper structure such as a bridge, and both ends of the girder may be supported by a pair of posts. The sectional height of the girder should be designed in consideration of the load acting on the girder in normal conditions, that is, the working load, as well as the load acting on the girder under extreme conditions, that is, the ultimate load.

That is, the height of the girder is inevitably larger than that of the case where only the working load is considered.

However, as the height of the girder increases, the height of the bridge, that is, the height from the ground to the girder, decreases, so there is a problem that the utilization of the lower space of the bridge is limited by that much. Therefore, there is a need for a method that can reduce the height of the girder in normal times.

Republic of Korea Patent Publication No. 10-1538730 (2015.07.23, precast concrete hollow slab type transverse connection box girder for crossing rivers and a bridge construction method using the same)

An embodiment of the present invention provides a type-height variable girder including an anchor block assembly having a different shape when the working load and the ultimate load are applied.

On the other hand, other objects not specified in the present invention will be additionally considered within the range that can be easily inferred from the following detailed description and effects thereof.

According to one aspect of the present invention, a girder portion; a plate bar disposed below the girder and extending in the longitudinal direction of the girder; a pair of anchor block assemblies for fixing both ends of the plate bar to the girder; and a pair of inclined members having one end coupled to the plate bar between the pair of anchor block assemblies, extending upwardly inclinedly and the other end coupled to the anchor block assembly, wherein the lower flange of the girder part has a length of the girder part. A slot hole extending in the direction is formed, and the anchor block assembly includes: an anchor block seated on the plate bar, the other end of the inclined member coupled thereto; a bolt having a head portion seated on the lower flange, and a screw portion extending downward from the head portion and penetrating the anchor block and the plate bar through the slot hole; and a nut screwed to the lower end of the screw, wherein the plate bar is fixed to the girder part by frictional resistance between the head part and the lower flange while pre-tension is applied. A type height variable girder comprising a can be provided.

Both ends of the inclined member may be hinged to the plate bar and the anchor block.

Unlike the plate bar, the inclined member may be coupled in a state in which no pre-tension is applied.

When a load greater than or equal to a preset value is applied to the upper portion of the girder, the bolt may advance along the slot hole, and the inclined member may press down the plate bar to increase the distance between the girder and the plate bar. .

The upper surface of the anchor block is closed by the lower flange and includes an insertion hole connected to the slot hole due to the advancement of the anchor block, and the anchor block assembly includes: a spring seated on the bottom surface of the insertion hole; and a stopper member that is seated on the spring to compress the spring in the vertical direction, and is inserted into the slot hole by the elastic force of the spring when the insertion hole is connected to the slot hole to prevent the anchor block from moving backward. can do.

A cross-section of the girder may be I-shaped.

A length of the plate bar may be shorter than a length of the girder part, and both ends of the plate bar may be disposed between both ends of the girder part.

According to an embodiment of the present invention, when a load less than a preset value, for example, a working load is applied to the upper part of the girder part, the bolts constraining the anchor block to the girder part can maintain a stopped state, but the upper part of the girder part When a load greater than the preset value, that is, an ultimate load is applied, the anchor block can also advance while the bolt moves along the slot hole, which causes the inclined member to press down on the plate bar to increase the distance between the girder and the plate bar. have.

On the other hand, even if it is an effect not explicitly mentioned herein, it is added that the effects described in the following specification expected by the technical features of the present invention and their potential effects are treated as described in the specification of the present invention.

1 is a front view showing a variable height girder including an anchor block assembly according to an embodiment of the present invention;
Figure 2 is a cross-sectional view of the anchor block assembly of Figure 1,
3 and 4 are enlarged views of the anchor block assembly of FIG. 1,
5 and 6 are views for explaining the principle of operation of the type-height variable girder including the anchor block assembly of FIG. 1 .
It is revealed that the accompanying drawings are exemplified by reference for understanding the technical idea of the present invention, and the scope of the present invention is not limited thereby.

In the description of the present invention, if it is determined that the subject matter of the present invention may be unnecessarily obscured as it is obvious to those skilled in the art with respect to related known functions, the detailed description thereof will be omitted.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Hereinafter, an embodiment of a type-height variable girder including an anchor block assembly according to the present invention will be described in detail with reference to the accompanying drawings. and a redundant description thereof will be omitted.

1 is a front view showing a variable height girder including an anchor block assembly according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of the anchor block assembly of FIG. 1, and FIGS. 3 and 4 are the anchor block of FIG. This is an enlarged view of the assembly.

1 to 4 , the height variable girder 10 including an anchor block assembly according to an embodiment of the present invention includes a girder unit 100 , a plate bar 200 , and a pair of anchor block assemblies 300 . ) and a pair of inclined members 400 may be included.

The girder part 100 may extend in a horizontal direction, and both ends of the girder part 100 may be supported by a pair of posts (not shown).

The cross-section of the girder part 100 may be I-shaped. That is, the girder part 100 may be an I-type girder.

In this case, the slot hole 110a extending in the longitudinal direction of the girder part 100 may be formed in the lower flange 110 of the girder part 100 .

The slot hole 110a may be formed to penetrate the lower flange 110 in the vertical direction.

In addition, the slot hole 110a may be formed in each of the pair of lower flanges 110 extending in opposite directions from the lower end of the girder part 100 .

However, the present invention is not necessarily limited thereto, and the girder part 100 may be a girder of another shape, such as a box-type girder. In this case, the lower flange 110 may mean a portion formed in a plate shape under the girder in a girder of another shape, such as a box-shaped girder.

The plate bar 200 may be disposed to be spaced apart from the lower side of the girder unit 100 , and may extend in the longitudinal direction of the girder unit 100 .

The length of the plate bar 200 may be shorter than the length of the girder part 100 , and both ends of the plate bar 200 may be disposed between both ends of the girder part 100 .

For example, the end of the girder part 100 and the end of the plate bar 200 may be disposed to be spaced apart from each other in the longitudinal direction of the girder part 100 .

The reason for this configuration is that the plate bar 200 is configured to reduce the maximum bending moment appearing in the girder part 100, while the maximum bending moment may appear greatest in the center of the girder part 100 while the girder part ( This is because it may appear closer to zero toward both ends of the 100 , so there is no need to extend the plate bar 200 to both ends of the girder part 100 .

The pair of anchor block assemblies 300 may fix both ends of the plate bar 200 to the girder part 100 .

The anchor block assembly 300 may include an anchor block 310 , a bolt 320 and a nut 330 , and may further include a spring 340 and a stopper member 350 .

The anchor block 310 may be seated on the plate bar 200 and disposed between the girder part 100 and the plate bar 200 .

A first through hole 311 into which the bolt 320 is inserted may be formed in the anchor block 310, and an insertion hole (in an upper surface of the anchor block 310) into which the spring 340 and the stopper member 350 are inserted. 313) may be formed.

The insertion hole 313 may be disposed to be spaced apart from the first through-hole 311 in the longitudinal direction of the girder unit 100 , and may be formed with an adjacent end of the girder unit 100 along the longitudinal direction of the girder unit 100 . It may be disposed between the first through holes 311 .

Accordingly, the insertion hole 313 may be closed by the lower flange 110 of the girder part 100, but may be connected to the slot hole 110a when the anchor block 300 advances.

In this specification, unless otherwise specified, advancing of a component may mean that the component moves in a direction away from the adjacent end of the girder part 100, and reversing means that the component moves away from the girder part 100. 100) may mean moving toward the proximal end.

The bolt 320 and the nut 330 may fix the plate bar 200 and the anchor block 310 to the girder part 100 .

The bolt 320 may include a head portion 321 and a screw portion 323 extending downward from the head portion 321 .

The head part 321 may be seated on the lower flange 110 of the girder part 100 .

The screw part 323 may pass through the slot hole 110a to sequentially pass through the anchor block 310 and the plate bar 200 .

For example, the screw portion 323 may be inserted into the first through hole 311 of the anchor block 310 , and the second through hole 201 into which the screw portion 323 is inserted into the plate bar 200 is the plate. It may be formed to penetrate the bar 200 in the vertical direction.

Accordingly, the bolt 320 may move forward or backward along the slot hole 110a, but between the head portion 321 and the lower flange 110 due to the nut 330 being screwed to the lower end of the screw portion 323 . A static state can be maintained by the frictional resistance generated.

In particular, the plate bar 200 may be fixed to the girder part 100 by frictional resistance between the head part 321 and the lower flange 110 in a pre-tensioned state, that is, in a pulled state.

The spring 340 may be seated on the bottom surface of the insertion hole 313 , and in a state in which the insertion hole 313 is closed by the lower flange 110 of the girder part 100 , it is formed by the stopper member 350 . It can be compressed in the vertical direction.

The stopper member 350 may be seated on the spring 340 . For example, both ends of the spring 340 in the vertical direction may be coupled to the stopper member 350 and the anchor block 310 .

The pair of inclined members 400 may be disposed between the girder part 100 and the plate bar 200 between the pair of anchor block assemblies 300 .

Both ends of the inclined member 400 may be coupled to the plate bar 200 and the anchor block assembly 300 .

The inclined member 400 may have a plate bar or rod shape, but is not necessarily limited thereto.

The inclined member 400 may be inclined with respect to the longitudinal direction of the girder part 100 , and the upper end of the inclined member 400 may be hinged to the upper portion of the anchor block 310 , and of the inclined member 400 . The lower end may be hinged to the plate bar 200 .

Unlike the plate bar 200 fixed to the girder part 100 in a state in which pre-tension is applied, the inclined member 400 is in a state in which pre-tension is not applied, that is, in a state in which it is not pulled, the plate bar 200 and the anchor. may be coupled to block 310 . For example, the inclined member 400 may be installed after the plate bar 200 is fixed in a pre-tensioned state.

5 and 6 are views for explaining the operating principle of the type-height variable girder including the anchor block assembly of FIG. 1 .

5 and 6, when a load greater than a preset value, that is, an ultimate load is applied to the upper portion of the girder unit 100, the length of the plate bar 200 may increase due to bending deformation of the girder unit 100. Also, the restoring force of the plate bar 200 may be greater than the static friction force between the head part 321 and the lower flange 110 .

As a result, the bolt 320 may advance along the slot hole 110a, and the length of the plate bar 200 may be reduced.

In addition, when the bolt 320 starts to move forward, a kinetic friction force smaller than the static friction force may act between the head portion 321 and the lower flange 110 , and thereby, during the pre-tension applied to the plate bar 200 (stop A portion (of a size corresponding to the difference between the frictional force and the kinetic frictional force) may be used to reduce the length of the plate bar 200 to be smaller than the pre-tensioned state.

That is, when the length of the inclined member 400 is restored at the time of installation, the length from the position where the inclined member 400 is coupled to the plate bar 200 to the anchor block 310 may be reduced compared to the time of installation.

Accordingly, the plate bar 200 may be pressed downwardly by the inclined member 400 , thereby increasing the vertical distance between the girder part 100 and the plate bar 200 .

On the other hand, when a load less than a preset value, for example, a working load is applied to the upper part of the girder part 100 , even if the length of the plate bar 200 increases due to bending deformation of the girder part 100 , , since the static friction force between the head portion 321 and the lower flange 110 is greater than the restoring force of the plate bar 200 , the bolt 320 may maintain a stationary state.

Accordingly, when a working load is applied to the upper portion of the girder unit 100 , the vertical distance or the girder shape between the girder unit 100 and the plate bar 200 may be maintained substantially constant.

Meanwhile, the maximum bending moment appearing in the girder part 100 may be calculated as in Equation 1 below.

[Equation 1]

M _max = M _u - T _max * e

In Equation 1, M _max is the maximum bending moment appearing in the girder part 100 , M _u is the moment generated by the load applied to the upper part of the girder part 100 , T _max * e is the girder part 100 . It may mean a negative moment generated while the plate bar 200 is tensioned when a load is applied to the upper portion, respectively, and e may mean the height from the center line or the center of gravity of the girder part 100 to the plate bar 200 . have.

According to Equation 1, when a load greater than a preset value, ie, an ultimate load, is applied to the upper portion of the girder unit 100, when the distance between the girder unit 100 and the plate bar 200 increases, as e increases Because the negative moment increases, the maximum bending moment can be maintained at a manageable level despite the increase _{of M u .}

The protection scope of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the protection scope of the present invention cannot be limited due to obvious changes or substitutions in the technical field to which the present invention pertains.

10: height variable girder including an anchor block assembly 100: girder part
110: lower flange 110a: slotted hole
200: plate bar 201: second through hole
300: anchor block assembly 310: anchor block
311: first through hole 313: insertion hole
320: bolt 321: head portion
323: thread 330: nut
340: spring 350: stopper member
400: inclined member

Claims (7)

girder;
a plate bar disposed below the girder and extending in the longitudinal direction of the girder;
a pair of anchor block assemblies for fixing both ends of the plate bar to the girder; and
One end is coupled to the plate bar between the pair of anchor block assemblies, and a pair of inclined members extending upward and having the other end coupled to the anchor block assembly,
A slot hole extending in the longitudinal direction of the girder part is formed in the lower flange of the girder part,
The anchor block assembly,
an anchor block seated on the plate bar and having the other end of the inclined member coupled thereto;
a bolt having a head portion seated on the lower flange, and a screw portion extending downward from the head portion and penetrating the anchor block and the plate bar through the slot hole; and
Comprising a nut screwed to the lower end of the screw portion,
The plate bar is a variable-type girder including an anchor block assembly, characterized in that it is fixed to the girder part by frictional resistance between the head part and the lower flange in a state in which pre-tension is applied. According to claim 1,
Both ends of the inclined member are hinged to the plate bar and the anchor block. According to claim 1,
The inclined member is a variable height girder including an anchor block assembly, characterized in that, unlike the plate bar, the pre-tension is not applied. According to claim 1,
When a load greater than or equal to a preset value is applied to the upper portion of the girder, the bolt advances along the slot hole, and the inclined member presses down the plate bar to increase the distance between the girder and the plate bar. A type-height variable girder comprising an anchor block assembly comprising: 5. The method of claim 4,
The upper surface of the anchor block is closed by the lower flange and includes an insertion hole connected to the slot hole due to the advancement of the anchor block,
The anchor block assembly,
a spring seated on the bottom surface of the insertion hole; and
It is seated on the spring to compress the spring in the vertical direction, and when the insertion hole is connected to the slot hole, it is inserted into the slot hole by the elastic force of the spring, further comprising a stopper member to block the reverse of the anchor block Hyeonggo variable girder comprising an anchor block assembly, characterized in that. According to claim 1,
The cross-section of the girder part is a type-height variable girder including an anchor block assembly, characterized in that the I-shape. According to claim 1,
The length of the plate bar is shorter than the length of the girder part, and both ends of the plate bar are provided between the both ends of the girder part.

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