KR20240034919A - Load transfer system for remodeling using underground beam - Google Patents

Abstract

The present invention applies an upward force to the existing structure by tensioning the tension material embedded in the underground beam at the bottom of the new foundation when constructing an extension in a remodeling construction, thereby preventing the additional load due to the extension from being added to the existing foundation or piles and preventing the new structure from being added to the existing foundation or piles. This is about a load transfer system for remodeling extensions using underground beams that can resolve the load imbalance between existing piles and new piles by transferring them from the foundation to the new piles.
The present invention's load transfer system for remodeling extensions using underground beams is for transferring the load of the extensions during remodeling work to expand an existing structure. It includes a new foundation extending on both sides of the existing foundation at the bottom of the existing structure; and an underground beam that is provided at the lower part of the new foundation on both sides and applies an upward force to the existing structure by introducing an upward camber due to the tension of the tendons provided inside. It is characterized by being composed of.

Description

Load transfer system for remodeling extension using underground beam {Load transfer system for remodeling using underground beam}

The present invention applies an upward force to the existing structure by tensioning the tension material embedded in the underground beam at the bottom of the new foundation when constructing an extension in a remodeling construction, thereby preventing the additional load due to the extension from being added to the existing foundation or piles and preventing the new structure from being added to the existing foundation or piles. This is about a load transfer system for remodeling extensions using underground beams that can resolve the load imbalance between existing piles and new piles by transferring them from the foundation to the new piles.

30 years have passed since the construction of the first new cities where large-scale apartments were supplied, and the number of aging apartments is rapidly increasing. Interest in remodeling as an alternative is increasing due to the recent strengthening of private reconstruction regulations.

Remodeling is the act of major repairs or extending or remodeling part of a building to prevent deterioration of the building or improve its function (Article 2, Paragraph 1, Item 10 of the Building Act). Accordingly, unlike new construction or reconstruction, it refers to activities that preserve existing buildings without demolishing them, maintaining the physical performance of the building in use while improving social performance.

Among these remodeling projects, there is a lot of interest in extensions that can increase the total floor area of existing buildings.

Apartment remodeling includes a horizontal extension method, in which a new extension is built horizontally next to the existing structure, and a vertical extension method, in which a new extension is built on top of the existing structure to increase the number of floors. Since the vertical load increases in all of the above methods, additional piles must be constructed to support the additional vertical load due to expansion.

However, even if additional piles are installed, the load burden on existing piles inevitably increases, so load imbalance between new piles and existing piles is inevitable.

In addition, existing piles and newly constructed reinforced piles have different frictional forces due to the difference in displacement of the surrounding ground, and the amount of elastic deformation of the piles is also different, showing different behavior characteristics.

In Registered Patent No. 10-1826086, instead of structurally integrating the vertical extension and the horizontal extension through post-tension, the vertical load of the vertical and horizontal extension is structurally separated from the existing building, so that the vertical load of the vertical and horizontal extension is transferred to the existing building. A technology that minimizes the burden on vertical and horizontal expansion parts is disclosed.

However, in the above registered patent, since the extension and the foundation supporting the existing building are connected to each other, the load of the extension is inevitably added to the existing piles supporting the existing building through the foundation.

Publication Patent No. 10-2021-0152183 discloses a technology for separating the horizontal extension from the existing building and connecting them with a damper.

However, since the above prior art completely separates the extension from the existing building, it is difficult to functionally integrate the horizontal extension with the internal rooms of the existing building.

In order to solve the above problems, the present invention prevents the additional load of the structure due to the extension during remodeling work from being added to the existing foundation or existing piles and transfers it to the new foundation or new piles, thereby reducing the load between the existing piles and the new piles. We aim to provide a load transfer system for remodeling extensions using underground beams that can resolve imbalances.

The present invention according to a preferred embodiment is for transferring the load of the extension portion during remodeling work to extend an existing structure, and includes a new foundation extending on both sides of the existing foundation at the bottom of the existing structure; and an underground beam that is provided at the lower part of the new foundation on both sides and applies an upward force to the existing structure by introducing an upward camber due to the tension of the tendons provided inside. Provides a remodeling extension load transfer system using an underground beam, characterized in that it consists of.

The present invention according to another preferred embodiment is remodeling using an underground beam, wherein the underground beam is formed to protrude from both ends of the existing structure in plan, and support piles for supporting the load of the underground beam are provided at the lower end of the underground beam. Provides an extension load transfer system.

The present invention according to another preferred embodiment provides a load transfer system for a remodeling extension using an underground beam, wherein the extension is constructed on top of the new foundation so that one side of the extension is connected to the existing structure.

The present invention according to another preferred embodiment provides a load transfer system for a remodeling extension using an underground beam, characterized in that a new pile is provided at the lower part of the new foundation inside or outside the underground beam.

The present invention according to another preferred embodiment is for transferring the load of the extension part during remodeling work to extend an existing structure, including the steps of (a) excavating the lower ground on both sides of the existing foundation below the existing structure to form a trench respectively; (b) constructing an underground beam inside the trench; (c) pouring concrete on top of the underground beam to construct a new foundation extending from the end of the existing foundation below the existing structure; (d) applying compressive prestress to the lower part of the underground beam to introduce upward camber; and (e) constructing an extension to the existing structure; Provides a remodeling extension load transfer method using an underground beam, characterized in that it includes.

The present invention according to another preferred embodiment arranges the tension material in the longitudinal direction of the trench after forming the trench in step (a), so that the tension material is buried inside the concrete when constructing the underground beam in step (b), and the ( A remodeling extension part load transfer method using an underground beam is provided, characterized in that upward camber is introduced into the underground beam by tensioning the tension member of the underground beam in step d).

The present invention according to another preferred embodiment is to arrange the sheath pipe in the longitudinal direction in the trench after forming the trench in step (a), so that the inside of the sheath pipe is formed after the construction of the underground beam is completed in step (b) or (c). A tension member is inserted into the ground beam, and in step (d), an upward camber is introduced into the underground beam by tensioning the tension member of the underground beam.

In the present invention according to another preferred embodiment, in step (a), the trench is formed to protrude beyond both ends of the existing structure in plan, and support piles are constructed in the ground outside the existing structure of the trench before or after formation of the trench. A remodeling extension load transfer method using an underground beam is provided.

In the present invention according to another preferred embodiment, in step (c), after completion of construction of the new foundation, a partial layer of the lower part of the extension is pre-constructed so that one side is connected to the existing structure, and in step (e), the upper part of the extension is A remodeling extension load transfer method using an underground beam is provided, which is characterized by constructing the remaining floor.

The present invention according to another preferred embodiment provides a load transfer method for a remodeling extension using an underground beam, wherein before step (c), new piles are constructed in the lower ground at the location where the new foundation is to be constructed.

According to the present invention, when expanding in a remodeling construction, a tension material is buried and installed in the ground beam at the bottom of the new foundation formed on both sides of the existing foundation below the existing structure, and the tension material is tensioned to introduce compressive prestress to the lower part of the ground beam. A load transfer system for remodeling extensions using can be provided.

Accordingly, an upward camber is introduced in the underground beam, and the resulting upward force is transmitted to the new and existing foundations, thereby reducing the load burden on the existing piles, preventing the load due to the extension from being added to the existing foundation or piles and preventing the new foundation from being added. By transferring to new piles, load imbalance between existing piles and new piles can be resolved.

1 is a perspective view showing the load transfer system of the present invention.
Figure 2 is a diagram showing the concept of introducing upward force by underground beam camber.
Figure 3 is a longitudinal cross-sectional view showing a state in which a new pile is installed.
Figure 4 is a longitudinal cross-sectional view showing the installation state of the existing structure.
Figure 5 is a longitudinal cross-sectional view showing a state in which trenches are formed on both sides of an existing foundation.
Figure 6 is a longitudinal cross-sectional view showing the underground beam in a constructed state.
Figure 7 is a longitudinal cross-sectional view showing a state in which a new foundation has been constructed.
Figure 8 is a cross-sectional view showing a state in which an upward camber is introduced into an underground beam.
Figure 9 is a longitudinal cross-sectional view showing a state in which the horizontal extension part is constructed.
Figure 10 is a cross-sectional view showing a state in which support piles are constructed on the bottom surfaces of both ends of the trench.
Figure 11 is a perspective view showing a state in which camber is introduced to the underground beam in a state in which the lower part of the extension part has been pre-constructed.
Figure 12 is a perspective view showing a state in which new piles are installed in the lower part of the new foundation.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

Figure 1 is a perspective view showing the load transfer system of the present invention, and Figure 2 is a diagram showing the concept of introducing upward force by the camber of the underground beam.

As shown in Figures 1 and 2, the load transfer system for the remodeling extension unit using an underground beam of the present invention is for transferring the load of the extension unit (3) during remodeling work to extend the existing structure (2). (2) a new foundation (31) extending on both sides of the existing foundation (21) at the bottom; and an underground beam (4) which is provided at the lower part of the new foundation (31) on both sides and applies an upward force to the existing structure (2) by introducing an upward camber due to the tension of the tension member (41) provided inside. It is characterized by being composed of.

The present invention prevents the additional load of the structure due to the extension part (3) from being added to the existing foundation (21) or existing piles (22) in horizontal extension remodeling construction, etc., and transfers it to the new foundation (31) or new piles (32). By doing so, it is intended to provide a load transfer system (1) for the remodeling extension using an underground beam that can resolve the load imbalance between the existing pile (22) and the new pile (32).

The present invention is applied to remodeling work that extends an existing structure (2) such as an apartment complex.

The present invention is particularly intended for horizontal expansion remodeling work in which a horizontal expansion part (3) is newly installed on the side of the existing structure (2), but in vertical expansion remodeling work, the additional load due to vertical expansion can be transferred to the outside of the existing structure (2). It can also be applied if necessary.

The lower part of the existing structure (2) is provided with an existing foundation (21) and existing piles (22). In other words, the existing structure (2) refers to the superstructure on top of the existing foundation (21).

The existing foundation 21 may be a mat foundation provided over the entire lower area of the existing structure 2.

New foundations 31 are constructed on both sides of the existing foundation 21.

The new foundation 31 extends from the existing foundation 21 and is integrally formed, so that it protrudes outward from the existing foundation 21.

In the embodiment of FIG. 1, the new foundation 31 was formed to be long along the longitudinal direction (long side direction) of the existing structure 2 at the front and rear of the existing structure 2, respectively.

The underground beam (4) is provided at the lower part of each new foundation (31).

The underground beam (4) is formed continuously and long in the longitudinal direction of the new foundation (31).

The underground beam 4 may be an RC member cast in situ or a PC member manufactured in a factory.

Tension members 41 are embedded and installed inside the underground beam 4.

The tension member 41 may be arranged in a straight line at the lower part of the underground beam 4 or curved in the form of a downward convex parabola as shown in FIG. 2.

The end of the tension member 41 is exposed to the end of the underground beam 4, and an anchor 42 for anchoring and tensioning the tension member 41 may be provided at the end of the underground beam 4.

When the tension member 41 is tensioned in a state in which the underground beam 4 and the new foundation 31 are formed integrally, and compressive prestress is introduced to the lower part of the underground beam 4, an upward camber is formed in the underground beam 4. ) is formed (Figure 2).

When camber is introduced to the underground beam (4) in this way, an upward force acts on the new foundation (31), and the upward force is transmitted to the existing foundation (21) integrally connected to the new foundation (31).

Accordingly, the load burden of the existing pile 22 is reduced in advance, so that the increase in load due to the extension part 3 during construction of the extension part 3 can be offset.

The magnitude of the upward force caused by the underground beam (4) can be set by structural calculation to correspond to the additional load expected to be added to the existing pile (22) due to the extension portion (3).

As shown in FIGS. 1 and 2, the underground beam 4 is formed to protrude from both ends of the existing structure 2 in plan, and the load of the underground beam 4 is applied to the lower part of the end of the underground beam 4. A support pile (5) may be provided to support it.

In order to apply an upward force to the new foundation 31, the existing foundation 21, and the existing structure 2 by the upward camber of the underground beam 4, the reaction force acting on the underground beam 4 due to this upward force must be supported. shall.

For this purpose, the ends of the underground beam (4) may be protruded to both ends of the existing structure (2), and support piles (5) may be provided at the lower part of the protruding underground beam (4).

That is, the support piles 5 are provided on the outside of each of the four corners of the existing structure 2, and both ends of each underground beam 4 on both sides of the existing structure 2 are mounted on the top of the support piles 5. .

Accordingly, when an upward force is applied to the existing structure (2) due to the camber of the underground beam (4), the resulting reaction force can be supported by the support piles (5) at both ends.

An enlarged support portion 40 with an enlarged cross-section may be formed at the end of the underground beam 4 so that the end of the underground beam 4 can be stably mounted on the top of the support pile 5.

As shown in FIG. 1, the extension part 3 may be constructed on the upper part of the new foundation 31 so that one side is connected to the existing structure 2.

That is, the extension part 3 may be horizontally extended to extend from one side of the existing structure 2.

In this case, the extension part 3 is constructed on the upper part of the new foundation 31.

Tension members 41 of the underground beam 4 are tensioned to introduce camber into the underground beam 4 and apply an upward force to the existing structure 2 to reduce the load on the existing pile 22, and then the extension part. Part or all of (3) can be constructed.

Accordingly, even if the load of the horizontal extension part (3) joined to one side of the existing structure (2) is transmitted to the existing foundation (21) and the existing pile (22) through the existing structure (2), the load of the existing pile (22) Because they have been reduced in advance, they cancel each other out and ultimately there is no additional load burden on the existing pile (22).

That is, during horizontal expansion, the load transmitted to the existing pile 22 can be transferred to the outside of the support pile 5, etc., thereby preventing an increase in the load on the existing pile 22.

Figure 3 is a longitudinal cross-sectional view showing a state in which a new pile is installed.

As shown in FIGS. 1 and 3, a new pile 32 may be provided at the lower part of the new foundation 31 inside or outside the underground beam 4.

In the present invention, the load transmitted to the existing pile 22 is transferred to the support pile 5 through the underground beam 4, and the support pile 5 is subjected to a reaction force caused by the upward force of the underground beam 4, that is, The additional load expected to be added to the existing pile (22) is supported by the extension part (3).

Therefore, the remaining load due to the extension section (3) must be supported by installing separate reinforcing piles.

For this purpose, a new pile 32 can be installed at the lower part of the new foundation 31.

That is, the total load due to the new construction of the extension portion 3 is shared and supported by the support pile 5 and the new pile 32.

In order to smoothly transmit the upward force due to the camber of the underground beam 4 to the existing foundation 21, it is preferable that the underground beam 4 is provided close to the existing foundation 21. In this case, the newly installed pile 32 may be provided on the outside of the underground beam 4 so as not to interfere with the underground beam 4.

If necessary, the underground beam 4 may be installed on the outside and the new pile 32 may be installed on the inside.

FIG. 4 is a longitudinal cross-sectional view showing the installation state of the existing structure, and FIG. 5 is a longitudinal cross-sectional view showing a state in which trenches are formed on both sides of the existing foundation.

The present invention's remodeling extension part load transfer method using an underground beam is for transferring the load of the extension part (3) in remodeling work to extend the existing structure (2), (a) the existing foundation below the existing structure (2) ( 21) Excavating the lower ground on both sides to form each trench (10); (b) constructing an underground beam (4) inside the trench (10); (c) pouring concrete on top of the underground beam (4) to construct a new foundation (31) extending from the end of the existing foundation (21) at the bottom of the existing structure (2); (d) applying compressive prestress to the lower part of the underground beam (4) to introduce upward camber; and (e) constructing an extension part (3) in the existing structure (2); It is characterized by being composed of a.

The present invention's load transfer method for remodeling extensions using underground beams is for constructing the load transfer system for remodeling extensions using underground beams as described above with reference to FIGS. 1 to 3.

In step (a), the lower ground on both sides of the existing foundation 21 below the existing structure 2 is excavated to form a trench 10, respectively.

That is, with the existing structure 2 installed as shown in FIG. 4, the lower ground on both sides of the existing foundation 21 is excavated to form the underground beam 4 to form a trench 10 to a predetermined depth (FIG. 5) .

The trench 10 may be formed long on both sides of the long side of the existing structure 2.

Figure 6 is a longitudinal cross-sectional view showing the underground beam in a constructed state.

Next, as shown in FIG. 6 (b), an underground beam 4 is constructed inside the trench 10.

If the underground beam 4 is an RC member cast in situ, the underground beam 4 can be formed by placing reinforcing bars inside the trench 10 and pouring concrete.

When the underground beam 4 is a PC member, the underground beam 4 can be constructed by lifting the previously manufactured underground beam 4 and placing it inside the trench 10.

Figure 7 is a longitudinal cross-sectional view showing the state in which the new foundation has been constructed.

And, as shown in FIG. 7 (c), concrete is poured on the upper part of the underground beam (4) to construct a new foundation (31) extending from the end of the existing foundation (21) below the existing structure (2).

A new foundation (31) extending from the end of the existing foundation (21) is constructed on the upper part of the underground beam (4).

The new foundation 31 on top of the underground beam 4 can be structurally integrated with the underground beam 4 to form a T-shaped beam together with the underground beam 4.

When the underground beam 4 is an RC member, the new foundation 31 can be constructed simultaneously with the underground beam 4 to form the underground beam 4 and the new foundation 31 as an integrated member.

If the underground beam (4) is a PC member, the new foundation (31) and the underground beam (4) can be integrated by protruding anchorage reinforcement on the upper part of the underground beam (4) and pouring new foundation concrete on the upper part. .

Figure 8 is a cross-sectional view showing a state in which an upward camber is introduced into an underground beam.

Thereafter, as shown in FIG. 8 (d), compressive prestress is applied to the lower part of the underground beam 4 to introduce an upward camber.

After completing the construction of the underground beam 4 and the new foundation 31, compressive prestress is introduced to the lower part of the underground beam 4 in step (d).

Accordingly, an upward camber is generated in the underground beam 4, and an upward force acts on the new foundation 31 and the existing foundation 21 connected thereto. The stress of the existing pile 22 is temporarily reduced by the upward force transmitted to the existing foundation 21.

Tension material 41 may be embedded inside the underground beam 4 in order to introduce compressive prestress to the lower part of the underground beam 4.

Figure 9 is a longitudinal cross-sectional view showing a state in which the horizontal extension part is constructed.

Finally, as shown in Figure 9 (e), an extension part (3) is newly installed in the existing structure (2).

That is, with an upward force acting on the existing foundation 21 due to the camber of the underground beam 4, the extension portion 3 is newly installed on the top of the new foundation 31 on both sides of the existing structure 2.

The load of the extension unit (3) is distributed to the existing foundation (21) and the new foundation (31), and the load due to the extension is also transmitted to the existing pile (22) below the existing foundation (21), but the load of the existing pile (22) The load caused by the extension portion 3 is offset by the temporary stress reduction.

Meanwhile, after forming the trench 10 in step (a), the tension member 41 is placed in the trench 10 in the longitudinal direction, so that the tension member 41 is placed inside the concrete during construction of the underground beam 4 in step (b). ) is buried, and in step (d), an upward camber can be introduced into the underground beam (4) by tensioning the tension member (41) of the underground beam (4).

Tension material 41 may be buried in the lower part of the underground beam 4 to introduce camber into the underground beam 4 by applying compressive prestress to the lower part of the underground beam 4.

For this purpose, after excavating the trench 10 in step (a), the tendon material 41 can be placed in a straight line or curved line inside the trench 10.

And in step (b), when constructing the underground beam (4), concrete can be poured inside the trench (10) to bury the tendon material (41) inside the underground beam (4). In this case, concrete is poured after being properly supported so that the anchorage 42 at the end of the tendon 41 is exposed to the outside of the end of the underground beam 4.

The tension member 41 may be inserted into the sheath pipe in advance, and then the sheath pipe may be placed with the tension member 41 inserted to introduce prestress through a non-attached post-tension method.

After forming the trench 10 in step (a), the sheath pipe is placed in the trench 10 in the longitudinal direction, and after completion of construction of the underground beam 4 in step (b) or (c), the inside of the sheath pipe is A tension member 41 is inserted into the ground beam 4, and in step (d), an upward camber can be introduced into the underground beam 4 by tensioning the tension member 41 of the underground beam 4.

In step (a), only the sheath pipe is placed in the trench (10), and in step (b), concrete is poured to form a duct inside the underground beam (4). Then, the tendon material (41) can be later inserted into the duct. there is.

When installing the tension member 41 using the non-attached post-tension method, the stress of the existing pile 22, the new pile 32, or the support pile 5 is monitored and added at the construction stage of the extension part 3 or after completion of construction. The stress can be redistributed by tensioning the tendon material 41.

Figure 10 is a cross-sectional view showing a state in which support piles are constructed on the bottom surfaces of both ends of the trench.

As shown in FIG. 10, in step (a), the trench 10 is formed to protrude beyond both ends of the existing structure 2 in plan, and the trench 10 is formed before or after the formation of the trench 10. ) A support pile (5) can be constructed in the ground outside the existing structure (2).

When support piles (5) are provided at both ends of the underground beam (4), the support piles (5) can be constructed before construction of the underground beam (4).

The support pile (5) may be constructed on the ground at the bottom of the trench (10) after excavating the trench (10). However, in some cases, the support pile (5) is first constructed after excavating the trench (10), and then the trench (10) area is installed. You can also dig.

The support pile 5 can be made of various types of piles, such as PHC piles, cast-in-place concrete piles, and steel pipe piles.

In step (b), the underground beam (4) may be constructed so that both ends are mounted on top of the support pile (5).

Figure 11 is a perspective view showing a state in which camber is introduced to the underground beam in a state in which the lower part of the extension part has been pre-constructed.

As shown in FIG. 11, in step (c), after completion of construction of the new foundation 31, the lower partial layer 3' of the extension part 3 is pre-constructed so that one side is connected to the existing structure 2. And, in step (e), the upper remaining layer (3") of the extension portion (3) can be constructed.

If the thickness of the new foundation 31 is not large, when upward camber is introduced to the underground beam 4, deformation occurs only in the new foundation 31 and the upward force may not be properly transmitted to the existing foundation 21. .

Therefore, before tensioning the tension member 41 of the underground beam 4 to demonstrate sufficient connection rigidity with the existing structure 2, the lower partial layer 3' of the horizontal extension portion 3 can be constructed first.

When the lower partial layer 3' of the extension part 3 introduces a camber to the underground beam 4 in a pre-construction state, the new foundation 31 on the upper part of the underground beam 4 and the extension on the upper part of the new foundation 31 The partial lower part of the sub-part (3') acts as a rigid body, and the new foundation (31) and the lower part of the extension part (3') are the existing foundation (21) and the lower part of the existing structure (2), respectively. As it is integrally joined with the floor, it exhibits sufficient connection rigidity, allowing the load from the underground beam (4) to be stably transmitted to the existing structure (2).

When the support pile (5) is installed at the end of the underground beam (4), the weight of the lower part of the extension part (3') is transferred to the support pile (5) through the underground beam (4) and the support pile (5) is supported by

Figure 12 is a perspective view showing a state in which new piles are installed in the lower part of the new foundation.

As shown in FIGS. 3 and 12, before step (c), new piles 32 may be constructed in the lower ground at the location where the new foundation 31 is to be constructed.

When the extension part (3) is horizontally expanded on one side of the existing structure (2), a new pile (32) is installed in the lower ground at the location where the new foundation (31) is to be constructed to support the load of the extension part (3). Construction can be done.

The new pile 32 is constructed in a position that does not overlap with the underground beam 4 in plan.

The new pile 32 can be constructed at any stage before the construction of the new foundation 31. That is, after constructing the trench 10 in step (a), new piles 32 may be constructed along with construction of the support piles 5, and construction of the underground beam 4 is completed in step (b). After this, a new pile (32) may be constructed.

1: Load transfer system
10: Trench
2: Existing structure
21: Existing Foundation
22: Existing piles
3: Extension part
3': lower part of the layer
3": Top remaining layer
31: New foundation
32: New pile
4: Underground beam
40: Expansion support part
41: Jang Jae
42: settlement area
5: Support pile

Claims (10)

This is to transfer the load of the extension part (3) during remodeling work to extend the existing structure (2).
A new foundation (31) extending on both sides of the existing foundation (21) below the existing structure (2); and
An underground beam (4) that is provided at the lower part of the new foundation (31) on both sides and applies an upward force to the existing structure (2) by introducing an upward camber due to the tension of the tension member (41) provided inside; A remodeling extension load transfer system using an underground beam, characterized in that it consists of.
In paragraph 1:
The underground beam (4) is formed to protrude from both ends of the existing structure (2) in plan, and a support pile (5) for supporting the load of the underground beam (4) is provided at the lower end of the underground beam (4). A load transfer system for remodeling extensions using underground beams.
In paragraph 1:
The extension part (3) is a remodeling extension part load transfer system using an underground beam, characterized in that one side is constructed on the upper part of the new foundation (31) so that one side is connected to the existing structure (2).
In paragraph 1:
A load transfer system for a remodeling extension using an underground beam, characterized in that a new pile (32) is provided at the lower part of the new foundation (31) inside or outside the underground beam (4).
This is to transfer the load of the extension part (3) during remodeling work to extend the existing structure (2).
(a) excavating the lower ground on both sides of the existing foundation (21) below the existing structure (2) to form a trench (10);
(b) constructing an underground beam (4) inside the trench (10);
(c) pouring concrete on top of the underground beam (4) to construct a new foundation (31) extending from the end of the existing foundation (21) at the bottom of the existing structure (2);
(d) applying compressive prestress to the lower part of the underground beam (4) to introduce upward camber; and
(e) constructing an extension part (3) in the existing structure (2); A remodeling extension load transfer method using an underground beam, characterized in that it includes.
In paragraph 5,
After forming the trench 10 in step (a), the tension material 41 is placed in the trench 10 in the longitudinal direction, so that the tension material 41 is placed inside the concrete during construction of the underground beam 4 in step (b). A remodeling extension part load transfer method using an underground beam, characterized in that an upward camber is introduced into the underground beam (4) by tensioning the tension member (41) of the underground beam (4) in step (d).
In paragraph 5,
After forming the trench 10 in step (a), the sheath pipe is placed in the trench 10 in the longitudinal direction, and after completion of construction of the underground beam 4 in step (b) or (c), the inside of the sheath pipe is Remodeling and expansion using an underground beam, characterized in that an upward camber is introduced into the underground beam (4) by tensioning the tension member (41) of the underground beam (4) in step (d). Negative load transfer method.
In paragraph 5,
In step (a), the trench 10 is formed to protrude beyond both ends of the existing structure 2 in plan, and is formed on the outside of the existing structure 2 of the trench 10 before or after forming the trench 10. A remodeling extension load transfer method using an underground beam, characterized in that support piles (5) are constructed in the ground.
In paragraph 5,
In step (c), after completion of construction of the new foundation 31, the lower partial layer 3' of the extension part 3 is pre-constructed so that one side is connected to the existing structure 2,
In step (e), a remodeling extension part load transfer method using an underground beam, characterized in that the upper remaining layer (3") of the extension part (3) is constructed.
In paragraph 5,
Before step (c), a remodeling extension load transfer method using an underground beam, characterized in that a new pile (32) is constructed in the lower ground at the location where the new foundation (31) is to be constructed.

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