RU19056U1 - MULTI-POINT WATER CROWDOW STRUCTURE UNDER THE BULK - Google Patents

Abstract

to the certificate for utility model No. "Multipoint culvert under the embankment

The utility model relates to the construction of artificial structures, in particular, culverts under embankments of railways and roads.

The technical result of the utility model is to expand the scope and reduce the cost of materials and labor.

The multi-point culvert under the embankment contains several (for example, two) located in parallel and combined into a single system of culverts 1, heads 2 with portal walls 3, a soil cushion 4 located in the pit 5 and a soil backfill 6.

The body of the pipe 1 in cross section consists of upper and lower arched parts. The upper arched part is made up of a metal corrugated arch 8 having a common well-supported cushion 7 and a reinforced concrete arch 9 connected to it. The lower arched part of the pipe body — the tray 10 is made of corrugated metal and laid convexly to the ground cushion 4. The lower arched part is connected to the upper arched part by means of an elastic-sliding, for example, bolted connection.

The culvert includes a tailor-type head, including a vertical wall 3 mounted perpendicular to the axis of the pipe.

The nortal wall 3 is divided into two parts, the upper 12, rigidly attached to the reinforced concrete arch 9, and the lower part 13, rigidly attached to the arch 10 of corrugated metal. The upper 12 and lower 13 parts of the portal wall are located in adjacent parallel

ESSAY

planes with the possibility of vertical movement relative to each other by means of) a sliding-sliding connection.

The length “In the upper part 12 of the portal wall on the plot towards the coast from the axis of the extreme pipe is determined from the expression:

and the length "b of the lower part 13 of the portal wall is equal to:

where h is the height of the upper part of the tail wall to fown passage, m;

S is the width of the hole of the pipe, m;

a - the slope of the slope in the direction of the longitudinal axis of the embankment, deg .;

0,8 W 1 - coefficient of working conditions.

The upper and lower parts of the portal walls in the middle between the axes of adjacent arches are cut by a vertical deformation seam 16, while the distance B from the axis of each arch to the deformation seam 16 is determined

from the expression: 5, - + / + - ,. w,

where p is the height of the horizontal section of the arch at the level of the section, PP, m;

q is the distance between the concrete parts of the arches, m;

where - +, where

0.8 yes, 1.5 - coefficient of working conditions.

In addition, the upper and lower parts of the metal arches can be made with different and independent from each other size, and the nortal wall can be made of metal elements, including

„S mh

B +,. And;

2 tga

h - + 3t, m,

Description

MULTI-POINT WATER CROWDOWS UNDER

The useful model refers to the construction of artificial structures, in particular, water-bearing structures under embankments of railways and roads.

Known metal corrugated culverting multi-point pipe containing two pipes, laid on a gravel sand then a pillow, soil backfill and heads. Yankovsky O.Ya. "Culverts beneath the Sates, M., Transport, 1982, p. 42-53.

The disadvantage of this pipe is that with a round pipe, there is a need for increased construction height, and with an elliptical pipe with a closed circuit, high stresses arise, and, as a result, there is a risk of loss of stability of the bottom part (tray) of the corrugated pipe.

The closest technical dryness and the achieved result to the claimed one is a corrugated culvert under the embankment, including the pipe body, consisting of an upper arched part formed of a corrugated metal arch having a common supporting area and a reinforced concrete arch combined with it, and a lower metal corrugated parts - tray, stacked

MKI EOIF 5/00

BULK

on a soil cushion located in the pit, and connected to the supporting platform of the upper arch part by means of an elastic-sliding connection, and a head equipped with portal walls rigidly connected to the ends of the upper and lower arch parts of the pipe, while each portal wall is divided into adjacent parallel planes with the possibility of vertical movement relative to each other, the upper part connected to the upper arched part, and the lower part connected to the lower arched part, and deformation first seam, wherein a length "In the upper part of portal wall is determined from the expression:

and the length b of the lower part of the portal wall is

where S is the width of the pipe hole, m;

0,8 / W 1 - coefficient of working conditions;

h - the height of the upper part of the portal wall to the level

travel, m;

and - the slope angle in the direction of the longitudinal axis of the embankment, deg.

The disadvantage of the culvert of such a construction is as follows:

- with an increase in the required pipe opening, a single-piece construction may be insufficient. When switching to a multi-point tube, the portal wall increases sharply in length. Since the portal wall contains mutually shifting upper and lower parts, with a long length, they can jam together;

„S TI

In -I, m

1 tga

L - + 3, w,

- with a further increase in the hole of each pipe, an increase in the size of the corrugation is required. The cost of such a corrugated sheet increases due to an increase in the consumption of metal and due to the complexity of manufacturing;

- if used in severe climatic conditions with a long winter period, it is possible to reduce the speed of construction due to the use of concrete elements in the design.

The technical result of the proposed utility model is to expand the scope and reduce the cost of materials and labor.

The essence of the proposed utility model is that in a multi-point culvert under the embankment, it contains several culverts located in parallel and combined into a system, heads with portal walls, a ground cushion located in the pit and a ground filling, while the body of each pipe in the cross section consists of an upper arched part formed of a corrugated metal arch having a common support pillow and a reinforced concrete arch combined with it, and a lower metal corrugation part of the tray, the convexity laid down on the ground cushion and connected to the supporting arch of the upper arch part by means of} Т1 sliding-sliding connection, and each portal wall is divided into upper parts connected in adjacent parallel planes with the possibility of vertical movement relative to each other, connected to the upper arched part and the lower part connected to the lower arched part, and the length of the upper "B and lower" b parts of the portal wall located on the site towards the coast from the axis of the edge her pipes, respectively, are equal to:

where S is the width of the pipe hole, m;

0,8 W 1 - coefficient of working conditions;

h is the height of the upper part of the north wall to the level

nroeza, m; a - the slope of the slope in the direction of the longitudinal axis of the spring, degrees.,

the upper and lower parts of the portal walls in the middle between the axes of adjacent arches are cut by a vertical expansion joint, and the distance BI from the axis of each arch to the expansion joint is determined from the expression:

where S is the width of the pipe hole, m;

p - the height of the horizontal section of the arch at the level of the P-P section, m;

7 - the distance of the concrete parts of adjacent arches, m;

in this case - +, w, /, where 0 ,, 1,5 - coefficient of conditions

work.

In addition, the corrugation dimensions of the lower and upper metal arches can be different and independent of each other. And the portal wall can be made of metal elements connected to each other.

The essence of the utility model is illustrated by drawings, where

figure 1 presents a section I-I in figure 2;

in Fig.2 section PP in Fig.1;

B - -h 3 / w, .i,

„5q

B, - + p +, m,

figure 4 - node L GTA fig.Z.

The culvert under the embankment contains several culverts 1 located in parallel and combined into a single system, the head 2 with the portal walls 3, the ground 4, located in the pit 5 and the ground backfill 6.

The body of the pipe I in cross section consists of the upper and lower arched parts. The upper arched part is formed of a support cushion 7 of a metal corrugated arch 8 and a reinforced concrete arch 9 connected to it.

The lower arched part of the body of the pipe 1 — the tray 10 is made of corrugated metal and laid convexly down to the ground digging 4. The lower arched part is connected to the upper arched part by means of a sliding-sliding connection of unit A (Fig. 4).

Structurally, this node can be made, for example, in the form of a bolted connection, while the bolts 11 in the support pillow 7 are fixed rigidly, and through the arch 10 pass through elongated cutouts that allow relative displacement of the arch 10 and the support pillow 7, and the elasticity of the connection is created by clamping nuts.

In the proposed culvert, a portal-type head is used, including a vertically} wall 3 mounted perpendicular to the axis of the pipe.

The vertical vertical wall 3 is divided into two parts, the upper 12, rigidly attached to the reinforced concrete arch 9, and the lower part 13, rigidly attached to the arch 10 of corrugated metal. The upper part 12 of the portal wall rises above the level of the drive 14 by a value of "a, which ensures traffic safety. The lower part 13 of the portal wall is buried in non-draining to prevent filtering under the pipe. The upper 12 and lower 13 parts of the portal wall are located in adjacent parallel planes with

the possibility of vertical movement relative to each other by means of an elastic-sliding connection. Between the contact planes of the upper 12 and lower 13 parts of the portal walls, a deformational seam 15 is made, which is a gap of 15-20 mm wide, filled with plastic waterproofing material.

The length "In the upper part 12 of the portal wall on the plot towards the coast from the axis of the extreme pipe is determined from the expression: and the length" b of the lower part 13 of the portal step is

where h is the height of the upper part of the portal wall to the level

travel, m;

S is the width of the hole of the pipe, m;

a - the slope angle in the direction of the longitudinal axis of the embankment, deg .;

0,8 m 1 - coefficient of working conditions.

The upper and other parts of the portal walls in the middle between the axes of adjacent arches are cut by a vertical deformation seam 16, while the distance B from the axis of each arch to the deformation of the seam 16 is determined from the expression:

where S is the width of the holes of the pipes, m;

p - the height of the horizontal section of the arch at the level of the section

P-P, m; 7 - the distance between the concrete parts of the arches, m;

„S mh

B-m, m

2 tga

B-- + 3t, m,

D S q 5, - + /. +,. ",

moreover, - +, w, 5, where 0.8 / i, 1.5 - coefficient of conditions

work.

In the case of uneven settlement of adjacent pipes, the gap in the expansion joint can expand. In order not to come out of the gap, the seam is closed from the inside with a protective screen 17. To drain the water from the sag, a drainage pipe 18 is arranged.

In addition, the upper metal arch can be made of interconnected corrugated elements with small corrugation, for example, 130 x 32.5 mm or less, and the lower part - the tray can be made of elements with large corrugation, for example, 152.4 x 50.8 mm or more.

The increase in the size of the corrugation is advisable only in relation to the lower arched part, but since its rigidity is created only due to the rigidity of the corrugation. It is impractical for the upper arched part to use large corrugation, since the required strength for perceiving the bending moment can be achieved by using a composite section, and the requirement of a minimum backfill thickness equal to 1/6 of the span, which can be achieved by using the same composite section.

The portal wall 3 can be made of interconnected metal elements, including corrugated. This makes it possible to reduce the amount of work performed mainly in the warm season.

The boundary of the slopes of the embankment at the pipe is shown by lines 19 and 20, the axis of symmetry of the pipe are shown by lines 21 and 22.

The features of the proposed culvert are as follows.

The presence of the expansion joint 16 allows you to ensure the normal operation of the creep-sliding connection for each pipe. The absence of deformation of the seam would lead to jamming of the upper and lower parts of the portal wall, constrained operation of the slip-sliding connection and overstrain of the tray part of individual arches.

As the opening of the structure increases, the demand for increasing rigidity increases sharply. The rigidity of the upper arched part can be technologically just increased due to additional elements that work: they are combined with an arch made of corrugated metal. Technological simplicity is achieved by the possibility of separating the installation of individual elements in time - first, the arch itself is mounted from separate corrugated sheets, and then the concrete part is made or any stiffeners are created. For the lower arched part, such a separation is practically impossible, since it should be carried out only from the outside, which for the lower arched part is under the already mounted corrugated arch. In connection with the foregoing, an increase in the rigidity of corrugated metal arches due to an increase in the size of the corrugation is required only for the lower part. It should be added that the calculation of the upper part is carried out mainly for bending, and the lower part for axial compression, taking into account stability. For the upper arched part, due to the presence of a rigid betongyuy arch, the requirements for the corrugated part urochnosti can be reduced. The above features for the construction of pipes with an increased span make it appropriate to separate the requirements for corrugated arches of the upper and lower arched parts. note that in the presence of additional elements, you will increase the seam; their rigidity of the upper arched part, the distance between the axes of adjacent pipes with a multi-point system is determined with an even thickness “p of additional concrete stiffness). arch (or element

Claims (3)

1. A multi-point culvert under the embankment, containing several parallel culverts arranged in a single system, consisting of an upper arched part formed of a corrugated metal arch having a common support pillow and a reinforced concrete arch combined with it, and a lower metal corrugated part - a tray, laid on an earth cushion placed in a pit connected to a support cushion of the upper arched part by means of an elastic-slip connection, and the head is equipped with portal walls, rigidly connected to the ends of the upper and lower arch parts of the pipe, with each portal wall is divided into adjacent in the parallel planes with the possibility of vertical movement relative to each other, the upper part connected to the upper arched part, and the lower part connected to the lower arched part, and the length of the upper "B" of the portal wall is

where S is the width of the pipe hole, m;
0,8 ≅ m ≅ 1 - coefficient of working conditions;
h is the height of the upper part of the portal wall to the level of passage, m;
α is the slope angle in the direction of the longitudinal axis of the embankment, deg.,
characterized in that the length of the lower "b" part of the portal wall located on the site towards the coast from the axis of the outer pipe is

and the upper and lower parts of the portal walls in the middle between the axes of adjacent arches are cut by a vertical expansion joint, while the distance B ₁ from the axis of each arch to the expansion joint is determined from the expression

where p is the height of the horizontal section of the arch at the level of section II-II, m;
q is the distance between the concrete parts of adjacent arches, m,
wherein

,
where m ₁ is the coefficient of working conditions, 0.8 ≅ m ₁ ≅ 1.5.  2. A multi-point culvert according to claim 1, characterized in that the corrugation dimensions of the lower and upper metal arches are different and independent of each other. 3. A multi-point culvert according to claim 1, characterized in that the portal wall is made of metal elements.