KR102088161B1 - Structure of self-stand retaining wall - Google Patents

Abstract

The present invention relates to a self-standing retaining wall structure capable of efficiently enduring earth pressure. The self-standing retaining wall structure of the present invention comprises: a plurality of first beams; a plurality of earthflow holes; a plurality of second beams; a plurality of retaining wall bodies; a tensile support member having a fixing plate, a tensile rod support plate, and a plurality of support plates; a binding plate having a binding hole; a tensile rod; a plurality of binding members; a plurality of fixing rods; and a plurality of connection rods.

Description

STRUCTURE OF SELF-STAND RETAINING WALL

The present invention relates to a self-supporting mudguard structure, and more particularly, to a self-supporting mudguard structure used to prevent soil or groundwater from entering a construction site when a trench is constructed to perform an underground structure construction work or the like. will be.

As is well known, before constructing structures in various excavation works such as foundation work, joint construction work, subway work, etc. of buildings excavating the ground to a certain depth, a mudguard structure must be constructed to secure the safety of the construction work site.

Construction of such a retaining structure proceeds to prevent the collapse of the ground due to excavation or slope pressure, and the structure is called a retaining wall, earth plate, earth wall, and the like.

In general, in the drilling work, after fixing and fixing the H beam at a predetermined depth to the ground at regular intervals on the ground to prevent the collapse or outflow of soil at the edges, incisions, etc. of the ground excavation, wood, bending between the H beam A retaining structure may be constructed by inserting an retaining wall such as an iron plate.

Accordingly, after driving the H beam to the ground, excavating the soil to a certain depth, and by sandwiching the earthen wall between each H beam, it is possible to prevent the surrounding soil from entering the construction site.

Here, the retaining wall must have a flexural strength (compressive strength) capable of supporting the earth pressure acting on the underground incision itself, but when the flexural strength is insufficient compared to the earth pressure, shear failure (broken) of the retaining wall occurs and H beam Due to the departure from the flange, it is very likely that the earth and sand will enter the construction site and cause a serious accident.

Therefore, in order to achieve the construction purpose of the retaining structure, the retaining wall must have a flexural strength (ie, compressive strength and tensile strength) corresponding to the earth pressure, and the H-beam acts as a support to support such a retaining wall not to be pushed back. do.

However, even when constructing the above-described mudguard structure, because of the limitation of the earth pressure that can withstand, it is necessary to reinforce the construction with a prop or the like inside the trench, so there is a problem in that the utilization of the interior space with the trench is poor.

In addition, due to the reinforcement work of the brace, etc., not only the material quantity increased, but also the problem that the construction cost and the construction period increased.

Therefore, there is a need for a self-supporting mudguard structure that solves the conventional problems as described above.

1. Korean Registered Patent No. 10-1179770 2. Korean Registered Patent No. 10-0528578

The present invention was invented to solve the problems of the prior art as described above. In the past, the mud structure has to be reinforced with a prop or the like inside the trench due to the limitation of the earth pressure that can withstand the construction. A self-supporting expression that enhances the usability of the interior space that has been dug, as well as the convenience of construction by forming a self-supporting earth retaining structure that can effectively withstand the earth pressure of the problem that the usability of the inner space that has been avoided is poor. The purpose is to provide a mudguard structure.

In order to achieve the above object, the present invention is provided to be provided parallel to the excavation surface and to be spaced apart from each other, and a plurality of first beams buried under the ground and between each of the first beams. A plurality of earth holes are provided in a stack, and a plurality of second beams, which are parallelly spaced to correspond to the first beam at the rear of the first beam, and have a lower portion buried in the ground, in a plate shape between each of the second beams. It is formed and provided, and each side is provided with a plurality of retaining walls fixed on the second beam, and a pair of symmetrically spaced apart at the rear of each of the second beams, each having a fixed plate formed in a plate shape. It is coupled to the rear side of the second beam, and the opposite side of the fixed plate facing each other is provided vertically with the fixed plate and is formed in a semi-circular shape and has a tensile sealing plate having a tensile sealing hole penetrating up and down inside. Each of the tension bar support plate and the fixed plate is provided with a tension support having a plurality of support plates formed in a plate shape to support the tension bar support plate, and each of the tensile support plates is formed in a cylindrical shape on the opposite side of the tension bar support plate. Each inner side is provided with a binding plate that is formed to be formed in a cylindrical shape at the rear of the second beam, and a binding plate for forming a binding hole that is inclined and narrowed in an opposing direction corresponding to the tensile sealing hole, and the upper and lower portions of each tension member are tensioned. A tensile bar is provided to extend through the binding hole of the sealing hole and the binding plate, and is provided to be insertable on the binding hole of the binding plate, respectively, and each of them is formed in a pair of semi-circularly symmetrical pairs, each protruding inside A plurality of fixing protrusions are formed, and a binding hole through which a tensile bar is inserted in each of the inside, and Each of the first and second beams is provided with angles that are formed to be long on both sides, respectively, and each is provided with a plurality of fixtures that are spaced up and down, and an angle that is long before and after between the first and second beams. It is formed in a shape is provided with a plurality, each of the front and rear ends are connected to the fixed and fixed, and the retaining wall is fixed by a plurality of wall fixtures, respectively, on the second beam, each of the wall fixtures can be indented and recessed It is formed is provided with a locking hole in which the rear end of the second beam is introduced, and an extension rod having a thread is formed on the outer periphery as well as protruding in front of the locking hole, and a thread is formed inside the extension rod to wrap the extension rod. An adjustment rod is provided so as to be provided, an adjustment portion having a hexagonal cross-section is formed in front of the adjustment rod, and in front of the adjustment portion It is formed in a plate shape and is provided with a support for contacting the retaining wall at the front, and provides a self-supporting retaining structure formed by a pair of nuts on the extension rod.

The self-supporting mudguard structure according to the present invention made as described above is a conventional mudguard due to the structure consisting of a first beam, a second beam, a earth hole, a mudguard wall, a tension support, a binding plate, a tension rod, a binding hole, a fixing bar, and a connecting rod. Compared to the structure, the limit of the earth pressure that can withstand the construction of the self-supporting mudguard structure is increased, so it is not necessary to carry out the reinforcement work with the props inside the trench, so the utilization of the space inside the trench is high, and the tension is increased according to the earth pressure. By controlling the tension of the rod, there is an advantage that can easily cope with the earth pressure.

1 is a schematic perspective view of a self-supporting mudguard structure according to the present invention,
Figure 2 is a schematic exploded perspective view of a part of the self-supporting retaining structure according to the present invention,
3 to 4 are schematic diagrams of a self-supporting earth retaining structure according to the present invention,
5 to 7 are schematic perspective views of a part of a self-supporting retaining structure according to the present invention;
8 to 10 are schematic cross-sectional views of a part of a self-supporting retaining structure according to the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 10, the self-supporting retaining structure according to the present invention is provided parallel to the excavation surface and is provided to have a predetermined distance therebetween, and a plurality of first beams 10 having a lower portion buried in the ground. , A plurality of each of the first beam 10 is provided with a plurality of earth holes 12 are stacked, and the rear of the first beam 10 is provided with parallel spacing corresponding to the first beam 10, the lower portion A plurality of second beams 14 buried in the ground and a plurality of earthen membranes formed on each of the second beams 14 are provided in a plate shape, and both sides are fixed on the second beams 14 The wall 16 and the second beam 14 are spaced up and down at the rear of each pair, and a pair is provided symmetrically, and each is provided with a fixed plate 18 formed in a plate shape to be coupled to the rear of the second beam 14 Being, the opposite side of the fixed plate 18 is provided vertically with the fixed plate 18 and the semi-circle It is formed and is provided with a tensile rod support plate 22 having a tensile seal hole 20 penetrated up and down inside, and formed in a plate shape to support the tension rod support plate 22 on each of the tension rod support plate 22 and the fixing plate 18. A plurality of support plates 24 are provided with a tensile support 26 and a tension rod support plate 22 of the tension support 26 is formed in a cylindrical shape on the opposite side and is provided, respectively, and the tension inside each The binding plate 30 is formed to be formed in a cylindrical shape at the rear of the second beam 14, and the binding plate 30 through which it penetrates up and down corresponding to the sealing hole 20 and which narrows obliquely in the opposite direction is formed. In addition, the upper and lower portions of the tension rods (20) of the tension support (26) and the binding rods (28) of the binding plate (30) are provided to extend through the extension rod 32, and the binding hole of the binding plate (30) (28) In addition to being provided so that each can be inserted, each of them is a pair of semi-circular mutually symmetrical It is formed, a plurality of fixed protrusions 34 protruding inside each of which is formed, and the binding sphere 36 into which the tension rod 32 is inserted, and the first beam 10 and the second beam are formed on each inside. Each of the angles formed on both sides of the front side of the front 14 is provided, and each is provided with a plurality of fixtures 38 which are spaced up and down, and the first beam 10 and the second beam 14 It is formed in a long angle shape in the front and rear between the plurality is provided, each of the front and rear ends are made of a connecting rod 40 that is fixed to the connecting rod 38.

First, it is provided to be provided parallel to the excavation surface and spaced apart from each other, and a plurality of first beams 10 having a lower portion buried in the ground are provided.

At this time, since the first beam 10 is to use a commonly used H beam, detailed description is omitted.

On the other hand, a plurality of earth holes 12 are stacked between each of the first beams 10, respectively.

At this time, the earth hole 12 is used to prevent the collapse or inflow of earth and sand, and may use a earth plate formed of wood, which is commonly used, but in the present invention, the earth hole 12 formed of a hard synthetic resin material 12 It is preferable to use).

On the other hand, the pressure measuring unit 42 is formed to have a gentle inward slope in the front of each of the earth holes 12 according to the present invention, and the sliding grooves 44 are formed inward on both sides. , Through grooves 46 are formed through the front of each of the sliding grooves 44, and are slidably inserted on the sliding grooves 44 on the respective sliding grooves 44, and correspond to the through grooves 46. It is to be provided with a sliding stand (50) having a gripping groove (48) that is inserted so as to be able to be gripped at a position.

At this time, the pressure measuring part 42 formed in the earth hole 12 is formed to be able to take measures by visually checking the pressure applied to the earth hole 12 to the earth hole 12 above a certain pressure. When the pressure is applied, the pressure measuring unit 42 is formed to be able to visually check the pressure applied to the earth hole 12 by bending or protruding forward.

In addition, the sliding groove 44 and the sliding table 50 formed in the earth hole 12 can be easily stacked with the earth hole 12 on a plurality of first beams 10 provided at various intervals. Unlike the conventional earth plate which is formed of wood to be formed so that the first beam 10 is slightly narrower or wider, the sliding bar 50 is easily adjusted on the sliding groove 44 to adjust the earth hole 12 It can be stacked on the first beam (10).

Parallel to the first beam 10 is provided at a rear side of the first beam 10, and a plurality of second beams 14 having a lower portion buried in the ground are provided.

At this time, the second beam 14 is formed of the same H beam as the first beam 10.

Each of the second beams 14 is formed in a plate shape, and each side has a plurality of retaining walls 16 fixed on the second beams 14.

At this time, the retaining wall 16 is formed in a plate shape of a metal material, but it is also possible to use the earth hole 12 according to the present invention.

On the other hand, the retaining wall 16 is preferably fixed through a bolt nut or welding between the second beams 14, but may also be fixed to a plurality of wall fasteners 52 described below.

At this time, the wall retainer 52 is provided to secure the convenience of construction and dismantling of the retaining wall 16, and the retaining wall 16 is provided with a plurality of wall anchors 52 on the second beam 14, respectively. ) Is fixed, and each of the wall fasteners 52 is formed in a concave-convex shape, and is provided with a locking hole 54 through which the rear end of the second beam 14 is inserted, and in front of the locking hole 54 In addition to being protruded, an extension rod 56 having a thread is formed on the outer circumference, and an adjusting rod 58 is provided in front of the extension rod 56 to form a thread on the inside to surround the extension rod 56, , In the front of the adjustment rod 58, an adjustment section 60 having a hexagonal cross section is formed, and in front of the adjustment section 60, it is formed in a plate shape so that the support 62 that the front hits the retaining wall 16 is provided. It is provided, and a pair of nuts 64 is provided on the extension rod 56.

On the other hand, due to the wall fastener 52, the retaining wall 16 can be fixed in a short time without any special processing or work, which has the advantage of saving construction time and dismantling time.

The second beam 14 is spaced up and down at the rear of each pair, and a pair is symmetrically provided, and each is provided with a fixed plate 18 formed in a plate shape, coupled to the rear of the second beam 14, and fixed plate 18 On the opposite sides facing each other, a tension rod support plate 22 is provided, which is provided vertically with the fixing plate 18 and is formed in a semicircle and has a tensile sealing hole 20 penetrated up and down inside, and includes a tension rod support plate 22. Each of the fixing plates 18 is provided with a tension support 26 having a plurality of support plates 24 formed in a plate shape to support the tension rod support plates 22.

At this time, the tension support 26 is a second beam 14 and the fixing beam 38 and the connecting rod 40 to be described later, the tensile force provided to the tensile rod 32 to be described later is connected to the second beam 14 It serves to provide the 1 beam 10, and the upper and lower portions of the first beam 10 and the upper and lower portions of the second beam 14, respectively, act on the rear side due to the tensile force provided to the tension support 26. It not only can easily withstand the pressure of the soil, but also prevents the soil from collapsing or entering,

The tensile support plate 22 of the tension support 26 is formed on the opposite side of the cylinder to be provided in a cylindrical shape, and each of the inner side is penetrated up and down corresponding to the tensile sealing hole 20 and narrowed in an inclined direction in the opposite direction. The paper is provided with a binding plate 30 on which a binding hole 28 is formed.

At this time, the binding plate 30 is formed of a metal material, and the binding hole 28 formed through the inside is formed to be inclined by serving as a fixing hole 32 through which a binding hole 36 to be described later is introduced. It is formed so that the binding port 36 can be easily fixed to the tension bar (32).

In addition to being formed in a cylindrical shape at the rear of the second beam 14, the upper and lower portions are provided to extend through the tensile sealing holes 20 and the binding holes 28 of the binding plate 30, respectively. A tension bar 32 is provided.

At this time, the tension bar 32 may be used in a variety of wire shapes or round rod shapes.

In addition, the tension bar 32 is one or a plurality of can be used at the same time, it is to be appropriately selected and used according to the tensile force to be supplied.

In addition to being provided so as to be respectively inserted on the binding hole 28 of the binding plate 30, each of which is formed as a pair of semi-circular mutually symmetrical, a plurality of fixed protrusions 34 protruding inside each are formed, , Each inner side is provided with a binding port 36 into which the tension bar 32 is inserted.

At this time, the binding hole 36 is formed to be inclined so that the outer periphery corresponds to the inclination formed in the binding hole 28, and is formed of a metal material, and the tension rod 32 can be easily fixed inside. In addition, the projections 34 to prevent slipping is formed.

On the other hand, on the binding hole 28 of each of the binding plates 30, springs 66 for providing tension in the direction in which the binding holes 36 face each other are provided in the direction in which the binding holes 36 face each other. It is more preferable that each spring 66 is provided with a binding bolt 68 which is provided to prevent the spring 66 from being detached and is fastened to the binding hole 28 of the binding plate 30, which is In addition to preventing the binding tool 36 from being detached from the binding plate 30, the binding tool 36 also serves to easily fix the tension bar 32.

Each of the first beam 10 and the second beam 14 is provided with angles that are formed to be elongated on both sides, respectively, and each is provided with a plurality of fixtures 38 which are spaced vertically.

At this time, a plurality of the fixing plate 38 serves to connect each of the first beam 10 and each of the second beams 14 to each other, thereby having a simultaneous resistance to pressure generated by soil and the like. will be.

In addition, between the first beam 10 and the second beam 14 is formed in a long angle shape in the front-rear direction, a plurality is provided, and each of the front-rear ends is connected to the fixing plate 38 and the connecting rod 40 to be fixed. It is provided, and thus the first beam 10 and the second beam 14 are connected to each other to have simultaneous resistance to the pressure of soil.

On the other hand, the method of providing a tensile force to the tension rod 32 is by pulling the upper portion of the tension rod 32 artificially by pulling the upper portion of the tension rod 32 while the upper and lower portions of the tension rod 32 are fixed by the binding tool 36 The tension force is provided to the 32, and the tension force provided to the tension rod 32 is adjusted according to the pressure provided by the soil.

The self-supporting retaining structure according to the present invention made as described above includes a first beam 10, a second beam 14, a earth hole 12, a retaining wall 16, a tension support 26, and a binding plate 30. , Due to the structure consisting of the tension bar 32, the binding port 36, the fixing bar 38 and the connecting rod 40, the limit of the earth pressure that can withstand the construction of the self-supporting earth retaining structure is increased compared to the conventional earth retaining structure. Since there is no need to carry out reinforcing work with a brace or the like inside the flag, there is an advantage in that it is possible to easily cope with the earth pressure by adjusting the tension of the tension bar 32 according to the earth pressure as well as having high utilization of the internal space that has been dug. .

10: 1st beam 12: Toryu-gu
14: second beam 16: retaining wall
18: fixed plate 20: tensile seal
22: tension bar support plate 24: support plate
26: tension support 28: binding ball
30: binding plate 32: tension rod
34: fixed projection 36: binding sphere
38: Fixture 40: Connecting rod
42: pressure measuring unit 44: sliding groove
46: through groove 48: grip groove
50: sliding table 52: wall fixture
54: hook 56: extension rod
58: adjusting rod 60: adjusting portion
62: support 64: nut
66: spring 68: binding bolt

Claims (5)

A plurality of first beams 10 provided in parallel with the excavation surface and provided with a predetermined distance therebetween, the lower part being buried in the ground;
A plurality of earth holes 12 each of which is stacked between each of the first beams 10;
A plurality of second beams 14 provided at a parallel distance corresponding to the first beam 10 at the rear of the first beam 10 and having a lower portion buried in the ground;
A plurality of retaining walls 16 formed in a plate shape between each of the second beams 14 and fixed on each side of the second beams 14;
The second beam 14 is spaced up and down at the rear of each pair, and a pair is symmetrically provided, and each is provided with a fixed plate 18 formed in a plate shape, coupled to the rear of the second beam 14, and fixed plate 18 On the opposite sides facing each other, a tension rod support plate 22 is provided, which is provided vertically with the fixing plate 18 and is formed in a semicircle and has a tensile sealing hole 20 penetrated up and down inside, and includes a tension rod support plate 22. Each of the fixing plate 18 is provided with a plurality of support plates 24 formed in a plate shape to support the tension rod support plates 22, a tension support 26;
The tension rod support plate 22 of the tension support 26 is formed in a cylindrical shape on the opposite side of the tension support 26, and is provided in each of the inside, and penetrates up and down corresponding to the tension sealing hole 20, and is narrowed in an inclined direction in the opposite direction. The binding plate 30 in which the binding hole 28 is formed;
In addition to being formed in a cylindrical shape at the rear of the second beam 14, the upper and lower portions are provided to extend through the tensile sealing holes 20 and the binding holes 28 of the binding plate 30, respectively. Tension bar 32;
Each of the binding plates 30 is provided to be insertable on the binding hole 28, and each is formed in a pair of semi-circularly symmetrical pairs, and a plurality of fixed protrusions 34 protruding from the inside are formed. , Each of the inner side of the tension rod 32 is a binding hole 36 is introduced;
In the front of the first beam 10 and the second beam 14 are provided with angles which are formed to be elongated on both sides, respectively, and each is provided with a plurality of fixtures 38 spaced apart vertically;
The first beam 10 and the second beam 14 is formed in a long angle shape in the front-rear direction, a plurality is provided, each front-rear end is connected to the fixed stand 38 and the connecting rod 40;
The retaining wall 16 is fixed to each of the second beams 14 by a plurality of wall fasteners 52, and each of the wall fasteners 52 is formed in a concave-convex shape that can be inserted into each of the second beams 14 A locking hole 54 through which the rear end is inserted is provided, and an extension rod 56 having a thread is formed on the outer periphery as well as protruding in front of the locking hole 54, and the inside of the extension rod 56 is inward. An adjusting rod 58 is provided to form a thread to surround the extension rod 56, and an adjusting portion 60 having a hexagonal cross-section is formed in front of the adjusting rod 58, and the adjusting portion 60 is provided. ) Is formed in a plate shape in the front of the self-supporting retaining structure, characterized in that the support 62 is provided to contact the retaining wall 16, a pair of nuts 64 is provided on the extension rod 56 . According to claim 1,
A pressure measuring unit 42 is formed in front of each of the earth holes 12 so as to have a gentle slope inward, and sliding grooves 44 are formed on both sides, and sliding grooves 44 are formed on both sides. Through grooves 46 are formed through the inside of each front, and the sliding grooves 44 are slidably inserted on the sliding grooves 44, and can be gripped at positions corresponding to the through grooves 46. A self-supporting retaining structure, characterized in that a sliding stand (50) having an inward gripping groove (48) is provided. According to claim 1,
The earth hole 12 is a self-supporting earth retaining structure characterized in that it is formed of a synthetic resin material. delete According to claim 1,
On the binding hole 28 of each of the binding plates 30, springs 66 are provided to provide tension in the direction in which the binding holes 36 face each other in the direction in which the binding holes 36 face each other. A self-supporting earth retaining structure characterized in that each spring 66 is provided with a binding bolt 68 which is provided to prevent the spring 66 from coming off, and is fastened to the binding hole 28 of the binding plate 30, respectively. .

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