KR20190081405A - Vibrator for lining concrete of tunnel and mold apparatus using the same - Google Patents

Abstract

The present invention relates to an apparatus to vibro-float a ceiling part during the placement of lining concrete in a tunnel with a mold apparatus (200). The vibro-floatation apparatus includes: a body (110) having a pipe structure; a vibration application part (120) installed in the body (110) to be able to be operated in a vertical direction; a vibration rod (130) installed in the upper part of the vibration application part (120); an extending part (140) in which the vibration rod (130) is installed to be able to be operated in a vertical direction; and an operating part (150) installed in the body (110). Therefore, the apparatus is capable of preventing the occurrence of a crack after curing.

Description

TECHNICAL FIELD [0001] The present invention relates to a vibrating compaction apparatus for a tunnel lining lining concrete, and a tunnel lining concrete formwork apparatus using the same. [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a field of construction technology, and more particularly, to a vibrating compaction apparatus for a tunnel lining lining concrete and a tunnel lining concrete formwork using the same.

After excavation (usually blasting) of tunnels, shotcrete is generally laid, and the interior of the tunnel is generally closed by pouring lining concrete.

Since the lining concrete is substantially repeated in the same shape on a large scale, the lining concrete has a body 21 formed to be movable along the longitudinal direction of the tunnel by wheels or rails, and a body portion 21 located adjacent to the inner surface of the tunnel The lining concrete is poured by the molding machine 20 having the mold part 22 provided on the outer side of the body 21 (Fig. 1).

In order to ensure that the poured concrete can be cured tightly without separating the material, the vibration should be compacted in an uncured state.

In the case of the lining concrete of the tunnel, a hole is made in a side wall of the mold part 22, and a vibration bar of the vibration compaction device is inserted therein to perform vibration compaction.

However, in the case of the ceiling portion of the lining concrete of the tunnel, it is not possible to make a hole in the ceiling portion of the mold portion 22 (since the unhardened concrete is poured), vibration compaction can not be performed, Has been pointed out as a main cause of cracking after curing.

The present invention has been made to solve the above problems and it is an object of the present invention to provide a vibration damping device for a tunnel lining concrete which can prevent vibrations of a lining concrete of a tunnel, And a molding apparatus for a tunnel lining concrete using the same.

In order to solve the above problems, the present invention is an apparatus for vibrating a ceiling portion during a lining concrete pouring operation of a tunnel by a molding machine (200), comprising: a main body (110) of a pipe structure; A vibration applying unit 120 installed in the main body 110 so as to be able to move along a vertical direction; A vibration bar (130) installed on the vibration applying part (120) so that the vibration applying part (120) vibrates and the upper part is buried in the unhardened lining concrete; And a lower end of the upper end is coupled to an upper end of the main body 110. The upper end of the vibration rod 130 is coupled to the upper end of the main body 110, An extension part 140 installed to be movable up and down; And a drive unit 150 installed in the main body 110 to enable the vibration applying unit 120 to be driven up and down. During the tunneling lining concrete pouring operation, the driving unit 150 applies the vibration applying unit 120 are upwardly driven so that the upper portion of the vibration bar 130 is buried in the unlapped lining concrete to vibrate the vibration and after the tunnel ceiling lining concrete pouring operation, (120) is driven downward and the upper part of the vibration bar (130) is separated from the lining concrete.

The driving unit 150 includes an extension rod 151 installed at a lower portion of the vibration applying unit 120; And an installation hole 152 formed at the lower end of the main body 110 so that the lower portion of the extension rod 151 is exposed to the lower side of the main body 110.

It is preferable that the installation hole 152 is formed with a female screw part and a male screw part is formed on the extension rod 151 and the vibration applying part 120 is driven up and down by the screw rotation of the extension rod 151 .

The main body 110 includes a guide tube 111 installed inside the vibration applying part 120 so as to be vertically movable; A body lower flange 112 integrally formed at a lower end of the guide tube 111 and having a through hole of the extension rod 151 at a deep portion thereof; And a closing plate 113 having a mounting hole 152 formed at a bottom portion of the lower flange and a bolt-connection case formed at a lower portion of the lower flange.

The main body 110 includes a guide tube 111 installed inside the vibration applying part 120 so as to be vertically movable; And a body upper flange 114 integrally formed on the upper end of the guide pipe 111 and having a through hole of the vibration bar 130 formed in a deep portion thereof, An extension pipe 141 coupled to the vibration hole 221 formed in the ceiling portion of the mold unit 220 of the apparatus 200 and having the vibration bar 130 installed so as to be vertically movable; An extension lower flange 142 integrally formed at the lower end of the extension pipe 141 and bolted to an upper portion of the upper body flange 114 and having a through hole of the vibration bar 130 formed at the center thereof .

The vibration applying unit 120 includes a supply port 121 for supplying pressure; And a discharge port 122 for discharging the pressure so that the supply port 121 and the discharge port 122 of the vibration applying unit 120 to be vertically driven are exposed to the outside, It is preferable that an exposure hole 115 having a directional elongated hole structure is formed.

The present invention relates to a molding apparatus (200) for tunnel lining concrete using the vibration compaction apparatus (100), comprising: a body portion (210) formed to be movable along a longitudinal direction of a tunnel; A mold part 220 installed on the outer side of the body part 210 so as to be positioned adjacent to the inner surface of the tunnel for pouring the lining concrete and having a vibration hole 221 in the ceiling part; And the vibrating compaction apparatus 100 coupled to the vibration hole 221 of the mold unit 220 so as to vibrate the fresh concrete laid on the top of the ceiling of the mold unit 220. [ A concrete lining 200 for a tunnel lining concrete is proposed.

It is preferable that the lower peripheral portion of the vibration hole 221 is welded to the upper peripheral portion of the extension portion 140 of the vibration-

It is preferable that a reinforcing rib 230 is installed on a lower peripheral portion of the vibration hole 221 and an upper peripheral portion of the extension portion 140 of the vibration-

A method of constructing a tunnel lining concrete using the molding machine (200), the method comprising: positioning the molding machine (200) at one point of a tunnel; A casting step of casting the lining concrete by the molding machine 200; The vibration applying unit 120 is driven upward by the driving unit 150 of the vibration compaction apparatus 100 so that the upper portion of the vibration rod 130 is buried in the lining concrete in the fresh concrete state, Compaction step; The vibration applying unit 120 is driven downward by the driving unit 150 of the vibration compaction apparatus 100 so that the upper portion of the vibration bar 130 is separated from the lining concrete ; Moving the molding machine (200) after the curing of the lining concrete to one point of the tunnel to position the molding machine (200) at another point of the tunnel; And repeating the pouring step, the vibrating compaction step, and the step of releasing the pivoting of the tunnel at another point of the tunnel.

The present invention proposes a vibrating compaction apparatus for a tunnel lining lining concrete and a tunnel lining concrete formwork apparatus using the same for preventing vibrations of the lining concrete of the tunnel from being generated after curing .

1 is a longitudinal cross-sectional view of a conventional tunnel forming apparatus.
2 shows an embodiment of the present invention,
2 is a longitudinal sectional view of a molding apparatus of a tunnel.
3 is a cross-sectional view of a molding device of a tunnel.
4 is a cross-sectional view of the first use state of the vibration damping apparatus;
5 is a cross-sectional view of a second use state of the vibration dampening device;
6 is a perspective view of the vibration compaction apparatus;

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

As shown in FIG. 2 and subsequent drawings, the present invention basically relates to an apparatus 100 for vibrating a ceiling portion of a lining concrete installation work of a tunnel by a formwork device 200.

Which comprises a body 110 of tubular structure; A vibration applying unit 120 (for example, an air vibrator) installed so as to be able to drive along the vertical direction inside the main body 110; A vibration bar 130 installed on the upper portion of the vibration applying unit 120 so that the vibration applying unit 120 vibrates and the upper part of the lining concrete can be embedded in the unhardened lining concrete; The upper end is coupled to the vibration hole 221 formed in the ceiling portion of the mold unit 220 of the molding machine 200 and the lower end thereof is coupled to the upper end of the body 110, An extension part 140 installed to be able to be installed; And a driving unit 150 installed on the main body 110 to enable the vibration applying unit 120 to be driven up and down (FIGS. 4 to 6).

Tunnel ceiling lining During the concrete pouring operation, the vibration applying unit 120 is driven upward by the driving unit 150, and the upper part of the vibration rod 130 is buried in the unlit lining concrete to vibrate.

After the tunnel ceiling lining concrete pouring operation, the vibration applying part 120 is driven downward by the driving part 150, and the upper part of the vibration rod 130 is separated from the lining concrete.

A tunnel-lining concrete formwork apparatus 200 using a vibration compaction apparatus 100 according to the present invention includes a body 210 formed to be movable by a wheel or a rail along a longitudinal direction of a tunnel; A mold part 220 installed on the outside of the body part 210 so as to be positioned adjacent to the inner surface of the tunnel for pouring the lining concrete and having vibration hole 221 in the ceiling part; And a vibrating compaction apparatus 100 coupled to the vibration hole 221 of the mold unit 220 so as to vibrate the fresh concrete laid on the top of the ceiling of the mold unit 220.

That is, as many vibrating compaction apparatuses 100 as required are installed on the ceiling portion of the mold unit 220 of the molding apparatus 200 (FIGS.

The method of constructing the tunnel lining concrete using the molding machine 200 is performed by the following process.

The molding machine 200 is positioned at one point of the tunnel and the lining concrete is poured by the molding machine 200 (FIG. 2).

The vibration applying unit 120 is driven upward by the driving unit 150 of the vibration damping apparatus 100 so that the upper portion of the vibration rod 130 is buried in the lining concrete in the fresh concrete state to perform vibration damping (FIG. 4) .

The vibration applying unit 120 is driven downward by the driving unit 150 of the vibration compaction apparatus 100 so that the upper portion of the vibration rod 130 is separated from the lining concrete.

After the curing of the lining concrete with respect to one point of the tunnel, the molding apparatus 200 is moved to the other point of the tunnel to position the molding apparatus 200 at another point of the tunnel, and then the pouring step, The enclosing release step is repeated (FIG. 3).

That is, according to the present invention, the vibration damping apparatus 100 is fixed to the through hole 221 of the ceiling portion of the mold unit 220 of the molding apparatus 200, and when the vibration damping is required, The vibrating unit 120 is driven by the driving unit 150 of the vibration damping apparatus 100 after the vibrating compaction is completed, while the upper part of the vibrating rod 130 is driven to be embedded in the lining concrete in the fresh concrete state, So that the upper portion of the vibrating shaft 130 is separated from the lining concrete, and the worker 200 is moved to perform work of the next section.

Since the vibrating compaction apparatus 100 is installed in the through hole 221 of the ceiling portion of the mold unit 220 so that the poured concrete is not likely to be poured through the through hole 221, And the vibrating rod 130 are driven up and down. Therefore, when vibration compaction is required, the vibrating compaction is carried out in an upward direction, and after the vibration compaction is completed, the molding apparatus can be moved downward by driving downward.

Therefore, unlike the prior art, since the lining concrete of the tunnel enables vibration compaction of the ceiling portion, it is possible to prevent the material of the lining concrete from being separated, thereby preventing the occurrence of cracks after curing.

Hereinafter, a specific configuration of the present invention will be described.

The driving unit 150 is not limited to a structure that can vertically drive the vibration applying unit 120 and the vibration bar 130 with respect to the fixed body 110.

An extension rod 151 provided below the vibration applying unit 120; And an installation hole 152 formed at the lower end of the main body 110 so that the lower portion of the extension rod 151 is exposed to the lower side of the main body 110. In this case, By vertically driving the rod 151, the vibration applying unit 120 can be easily moved up and down (Figs. 4 and 5).

In the case where the mounting hole 152 is formed with a female screw portion and a male screw portion is formed on the extending rod 151 and the vibration applying portion 120 is vertically driven by screw rotation driving of the extending rod 151, The vibration applying unit 120 can be stably and easily moved up and down by the vibration applying unit 120 and the vibration applying unit 120 can be stably positioned at a desired height, 5).

The main body 110 includes a guide tube 111 installed inside the vibration applying part 120 so as to be vertically movable; A body lower flange 112 integrally formed at the lower end of the guide tube 111 and having a through hole of an extension rod 151 at a deep portion thereof; And a closure plate 113 having a bolt coupling at the lower part of the lower flange and an installation hole 152 at the core part.

This is advantageous in that installation, replacement, maintenance, and the like of the vibration applying unit 120 such as an air vibrator can be easily performed by separating or coupling the main body lower flange 112 and the closing plate 113.

The lower peripheral portion of the vibration transmitting through hole 221 and the lower peripheral portion of the extension portion 140 of the vibration damping apparatus 100 may be formed in the same manner as the above- It is preferable that the upper peripheral portion has a solid welded structure.

When the reinforcing rib 230 is provided on the lower peripheral portion of the vibration hole 221 and the upper peripheral portion of the extension pipe 141 of the extension portion 140 of the vibration damping device 100, It is possible to prevent the loss of the lining concrete through the vibration hole 221 by the breakage of the coupling structure of the extension pipe 141 and the extension pipe 141.

The main body 110 includes a guide tube 111 installed inside the vibration applying part 120 so as to be vertically movable; And a body upper flange 114 integrally formed on the upper end of the guide pipe 111 and having a penetration hole of the swinging rod 130 formed in a deep portion thereof.

The extension part 140 is coupled to the vibration hole 221 formed in the ceiling part of the mold part 220 of the molding device 200 so that the vibration rod 130 can be vertically driven An installed extension pipe 141; And an extension lower flange 142 integrally formed at the lower end of the extension pipe 141 and bolt-connected to the upper portion of the upper flange 114 of the main body and having a through hole of the vibration bar 130 formed at the center thereof I can take it.

The upper end of the extension pipe 141 of the extension part 140 is fixed to the molded part 220 by welding or the like. When the above configuration is adopted, the extension part 140 and the main body 110 can be easily separated Therefore, there is an advantage that maintenance such as installation of the apparatus, replacement of parts, and cleaning can be easily performed.

The vibration applying section 120 (air vibrator) includes a supply port 121 for supplying pressure (air pressure); The supply port 121 and the discharge port 122 of the vibration applying unit 120 which are vertically driven on the side wall of the main body 110 are exposed to the outside It is preferable to form an exposure hole 115 having a longitudinally elongated hole structure.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100: Vibrating compaction device 110:
111: Guide tube 112: Lower flange of the main body
113: closing plate 114: upper body flange
115: Exposure hole 120: Vibration applying part
121: supply port 122:
130: vibrating shaft 140: extension part
141: extension pipe 142: extension part lower flange
150: driving part 151: extension rod
152: installation hole 200: formwork device
210: body part 220:
221: a vibration penetrating hole 230: a reinforcing rib

Claims (10)

A lining of a tunnel by a formwork device (200) An apparatus for vibrating a ceiling portion during concrete pouring work,
A tubular structure body 110;
A vibration applying unit 120 installed in the main body 110 so as to be able to move along a vertical direction;
A vibration bar (130) installed on the vibration applying part (120) so that the vibration applying part (120) vibrates and the upper part is buried in the unhardened lining concrete;
And a lower end of the upper end is coupled to an upper end of the main body 110. The upper end of the vibration rod 130 is coupled to the upper end of the main body 110, An extension part 140 installed to be movable up and down;
And a driving unit 150 installed in the main body 110 to enable the vibration applying unit 120 to be driven up and down,
During the operation of installing the tunnel ceiling lining concrete, the vibration applying unit 120 is driven upward by the driving unit 150 so that the upper part of the vibration rod 130 is buried in the lining concrete in an uncured state,
Tunnel ceiling lining After the concrete pouring operation, the vibration applying part 120 is driven downward by the driving part 150 so that the upper part of the vibration rod 130 is separated from the lining concrete. (100). The method according to claim 1,
The driving unit 150 includes:
An extension rod 151 installed at a lower portion of the vibration applying unit 120;
An installation hole 152 formed at a lower end of the main body 110 so that a lower portion of the extension rod 151 is exposed to the lower side of the main body 110;
(100) of the tunnel lining lining concrete. 3. The method of claim 2,
The installation hole 152 is formed with a female screw,
A male screw portion is formed on the extension rod 151,
Wherein the vibration applying unit (120) is driven up and down by the screw rotation driving of the extension rod (151). The method of claim 3,
The main body (110)
A guide pipe 111 installed inside the vibration applying unit 120 so as to be vertically movable;
A body lower flange 112 integrally formed at a lower end of the guide tube 111 and having a through hole of the extension rod 151 at a deep portion thereof;
A closure plate 113 having a bolt coupling at a lower portion of the lower flange and a mounting hole 152 formed at a center portion thereof;
(100) of the tunnel lining lining concrete. The method according to claim 1,
The main body (110)
A guide pipe 111 installed inside the vibration applying unit 120 so as to be vertically movable;
And a body upper flange 114 integrally formed on the upper end of the guide tube 111 and having a through hole of the vibration bar 130 formed at a deep portion thereof,
The extension (140)
An upper end coupled to the vibration hole 221 formed in the ceiling portion of the mold unit 220 of the molding apparatus 200 and having an extension pipe 141 installed therein so that the vibration rod 130 can be driven up and down;
An extension lower flange 142 integrally formed at the lower end of the extension pipe 141 and bolted to the upper portion of the main body upper flange 114 and having a through hole of the vibration bar 130 formed at the center thereof;
(100) of the tunnel lining lining concrete. The method according to claim 1,
The vibration applying unit 120 includes:
A supply port 121 for supplying pressure;
And an outlet (122) for discharging the pressure,
The side wall of the main body 110 is formed with an exposure hole 115 having a vertical elongated hole structure so that the supply port 121 and the discharge port 122 of the vibration applying unit 120 to be vertically driven are exposed to the outside. A vibrating compaction apparatus for a tunnel ceiling lining concrete (100). A tunnel-lining concrete formwork apparatus (200) using the vibration-tightening apparatus (100) according to any one of claims 1 to 6,
A body 210 formed to be movable along the longitudinal direction of the tunnel;
A mold part 220 installed on the outer side of the body part 210 so as to be positioned adjacent to the inner surface of the tunnel for pouring the lining concrete and having a vibration hole 221 in the ceiling part;
The vibrating compaction apparatus 100 coupled to the vibration hole 221 of the mold unit 220 so as to vibrate the fresh concrete laid on the top of the ceiling of the mold unit 220;
(200) for a tunnel lining concrete. 8. The method of claim 7,
The lower peripheral portion of the vibration hole 221 is welded to the upper peripheral portion of the extension portion 140 of the vibration damping device 100. 8. The method of claim 7,
Wherein a reinforcing rib (230) is installed on a lower peripheral portion of the vibration hole (221) and an upper peripheral portion of an extension portion (140) of the vibration damping apparatus (100) 200). A method of constructing a tunnel lining concrete using the dies (200) of claim 7,
Positioning the molding machine (200) at one point in the tunnel;
A casting step of casting the lining concrete by the molding machine 200;
The vibration applying unit 120 is driven upward by the driving unit 150 of the vibration compaction apparatus 100 so that the upper portion of the vibration rod 130 is buried in the lining concrete in the fresh concrete state, Compaction step;
The vibration applying unit 120 is driven downward by the driving unit 150 of the vibration compaction apparatus 100 so that the upper portion of the vibration bar 130 is separated from the lining concrete ;
Moving the molding machine (200) after the curing of the lining concrete to one point of the tunnel to position the molding machine (200) at another point of the tunnel;
Repeating the pouring step, vibration compaction step, and departure / departure step with respect to another point of the tunnel;
Wherein the method comprises the steps of:

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