JP2015067949A - Device and method for placing lining concrete and traveling centre - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve quality of lining concrete.SOLUTION: A device for placing lining concrete C in a placing space D formed between an inner peripheral surface t1 of a tunnel T and a mold form 3 includes a plurality of concrete pumps PA and PB capable of being simultaneously driven, and a plurality of force-feed pipes 10A and 10B connected to the concrete pumps PA and PB and guiding the lining concrete C to the placing space D, and the force-feed pipes 10A are disposed in positions different from each other in a tunnel longitudinal direction toward both sides in a tunnel width direction.

Description

  The present invention relates to an apparatus and method for placing lining concrete on an inner wall of a tunnel, and a mobile centle.

  In general, for secondary lining of the inner surface of the tunnel with concrete, a slide centle (movable centle) that can move in the tunnel longitudinal direction (front-rear direction) is entered into the tunnel, and the arch shape provided on this slide centle A method has been adopted in which a space for placing lining concrete is formed between the formwork and the inner peripheral surface of the tunnel, and the lining concrete pumped by a concrete pump is poured into the placing space.

  Moreover, in the following Patent Document 1, the other end of a pipe (here, “first pipe”) connected at one end to a concrete pump is connected to a pipe switching device. Four pipes (referred to as “second pipes”) are connected, and these four second pipes are connected to both sides in the width direction (left and right direction) on the front side of the mold, and both sides in the width direction on the rear side. It arrange | positions toward 4 places in total. And the technique of patent document 1 is pouring the lining concrete pressure-fed by the concrete pump in four places on the front, back, left, and right of the formwork by switching the four second pipes with the pipe switching device. Is configured to do. In each of the front, rear, left and right portions of the formwork, the tip of the second pipe is further connected to another pipe switching device, and three pipes (referred to as “third pipe”) are connected to this pipe switching device. Is connected. And it is comprised so that lining concrete may be laid in order in the lower stage, the middle stage, and the upper stage of a formwork by switching three 3rd piping with the said piping switching device.

  Further, in Patent Document 2 below, a pumping pipe having one end connected to a concrete pump is extended in the tunnel longitudinal direction to the center part in the formwork, and extends to both sides of the tunnel width direction at the tip of the pumping pipe. It is disclosed that three first branch pipes that connect in the tunnel longitudinal direction are connected to the front ends of the first branch pipes. And the technique of patent document 2 is the total of the front part, intermediate | middle part, and rear part in the right and left sides of a formwork through the 1st branch pipe and the 2nd branch pipe from the feed pipe through the lining concrete pumped by the concrete pump. It is configured to be placed at six locations simultaneously.

JP 2013-108243 A JP 2001-280094 A

In the technique described in Patent Document 1, lining concrete is placed in order in four places on the front, back, left and right of the formwork, so that the lining concrete is placed only on one side in the left-right direction or only one side in the front-rear direction. There will always be a situation. In this way, when lining concrete is placed only on one side in the left-right direction, a load from the already-laid lining concrete is applied in one direction to the left and right of the formwork, and this form causes the formwork to move in the left-right direction. There is a possibility that will be eccentric. In addition, when lining concrete is placed only on one side in the front-rear direction, the lining concrete expands greatly in the front-rear direction, and the aggregate and cement paste that is the material of the lining concrete can be easily separated. is there. In addition, lining concrete is placed separately in four places on the front, back, left, and right of the formwork, and in each place on the front, back, left and right, concrete is placed separately in the lower, middle, and upper stages. The time required for the transition to the location becomes longer, and as a result, the possibility of occurrence of a cold joint increases.
And since any of the above problems leads to deterioration of the quality of the lining concrete, it is important to solve these problems.

  On the other hand, in the technique described in Patent Document 2, because the lining concrete can be simultaneously placed on the front, middle, and rear of the left and right sides of the formwork, the problem of the technique described in Patent Document 1 can be solved at a stretch. I can see it. However, in actuality, since the one branch pipe is finally branched into six second branch pipes and the shapes of the second branch pipes are different from each other, the lining concrete in each second branch pipe The flow resistance is greatly different, and the amount of lining concrete poured into the front, rear, left and right six locations is biased. In particular, in the case of Patent Document 2, the flow resistance is extremely high in the second branch pipes on both the front and rear sides including the bent pipe, and more lining concrete is poured from the second branch pipe in the front and rear intermediate portion made of a straight pipe. The placed lining concrete greatly expands from the front and rear intermediate portion of the formwork to the front and rear sides, and the material is easily separated. Patent Document 2 describes that the amount of lining concrete outflow from the three second branch pipes is equalized by a valve provided in each second branch pipe. It is extremely difficult to equalize the flow rate of the engineered concrete only by adjusting the valve.

  This invention is made | formed in view of such a situation, and aims at improving the quality of lining concrete.

The present invention is an apparatus for placing lining concrete in a placement space formed between an inner peripheral surface of a tunnel and a formwork,
Multiple concrete pumps that can be driven simultaneously,
Individually connected to each concrete pump, and provided with a plurality of pumping pipes for guiding the lining concrete to the placement space,
The plurality of pumping pipes are disposed at positions different from each other in the tunnel longitudinal direction and toward both sides in the tunnel width direction.

  According to this configuration, by simultaneously driving a plurality of concrete pumps, lining concrete can be simultaneously placed on both sides in the tunnel width direction at a plurality of locations in the tunnel longitudinal direction. Therefore, it is possible to place the lining concrete in a short time. In addition, lining concrete is not placed only on one side in the tunnel width direction, and only a load directed to one side in the tunnel width direction does not act on the formwork, thus preventing eccentricity of the formwork. Can do. In particular, in each part in the tunnel longitudinal direction, the lining concrete pumped from the same concrete pump is distributed and placed on both sides in the tunnel width direction, so the lining concrete is placed evenly on both sides in the tunnel width direction. Thus, the eccentricity of the formwork can be prevented more reliably.

Further, since the lining concrete is simultaneously placed at a plurality of locations in the tunnel longitudinal direction, the spreading of the lining concrete in the tunnel longitudinal direction can be suppressed, and material separation of the lining concrete can be prevented.
In the present invention, on each side in the tunnel width direction, the plurality of locations in the tunnel longitudinal direction are not a plurality of branch pipes branched back and forth from one pipe as in Patent Document 2, but different concrete pumps. Since lining concrete is driven from a plurality of connected pumping pipes, it becomes easy to form the same shape (straight line, bending shape, etc.) of the plurality of pumping pipes, and the amount of lining concrete flowing out from both pipes Can be easily equalized.
In addition, since the lining concrete is simultaneously cast at a plurality of locations in the tunnel longitudinal direction and the width direction, it is possible to reduce the time required for the transition by reducing the connection of the pressure feeding pipe for the transition of the placement location. This can prevent the occurrence of cold joints. As described above, it is possible to construct a high-quality lining concrete.

The said structure WHEREIN: Each said pressure sending pipe can contain the main piping extended in the tunnel longitudinal direction in the said formwork, and the branch piping branched to the tunnel width direction both sides from the said main piping.
In this case, it is preferable that the main pipe is disposed at the center in the tunnel width direction in the mold.
With such a configuration, it becomes easy to uniformly supply the concrete from the main pipe arranged in the center in the tunnel width direction to both sides in the tunnel width direction via the branch pipe.

Moreover, it is preferable that the main pipes of the plurality of pressure feeding pipes are arranged one above the other.
With such a configuration, the plurality of main pipes can be arranged at the center in the tunnel width direction.

The branch pipe is preferably provided with a flow rate adjusting device for adjusting the flow rate of the lining concrete.
With such a configuration, it is possible to adjust the flow rate of the lining concrete so that the lining concrete is placed evenly on both sides in the tunnel width direction.

The branch pipe is preferably provided with a pressure gauge for measuring the pressure of the lining concrete.
With such a configuration, it is possible to detect whether or not concrete is evenly placed on both sides in the tunnel width direction.

The present invention is a method for placing lining concrete in a placement space formed between an inner peripheral surface of a tunnel and a formwork,
Each of the plurality of concrete pumps is characterized in that lining concrete is simultaneously placed on both sides in the tunnel width direction at mutually different positions in the tunnel longitudinal direction.

  The mobile centile of the present invention is characterized in that it includes a mold that forms a placement space for lining concrete between the inner peripheral surface of a tunnel and a pressure feeding pipe in the placement device.

  According to the present invention, the quality of lining concrete can be improved.

It is a front view which shows the placement apparatus of the lining concrete which concerns on one Embodiment of this invention. It is a whole side view of a driving device. It is a whole top view of a driving device. It is an enlarged view of the connection part of main piping and branch piping. (A) is explanatory drawing which shows the conventional placement state, (b) is explanatory drawing which shows the placement state of this invention. It is a front view which shows a part of mobile centile. It is a front view which shows the placement apparatus of the lining concrete which concerns on a modification.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a front view showing a lining concrete placing apparatus according to an embodiment of the present invention, FIG. 2 is an overall side view of the placing apparatus, and FIG. 3 is an overall plan view of the placing apparatus. is there.
In FIG. 1, this placing apparatus places secondary lining concrete (hereinafter simply referred to as “lining concrete”) C on the inner peripheral surface t1 of the tunnel T subjected to primary lining. Concrete pumps PA and PB for pumping the sliding centle (movable centle) 1 that forms the placement space D of the lining concrete C between the inner peripheral surface t1 of the tunnel T and the lining concrete C (green concrete) And pressure feeding pipes 10A and 10B for guiding the lining concrete C sent by the concrete pumps PA and PB to the placement space D.

  As shown in FIG. 1, the slide centle 1 can travel on a rail R laid on the floor surface in the tunnel T. The slide center 1 is sequentially set with a predetermined span from the wellhead side (left side in FIG. 2) to the face side (right side in FIG. 2) to form a placement space D (see FIG. 3) for the lining concrete C. It is like that. In this specification, the tunnel longitudinal direction (extension direction) may be referred to as the front-rear direction, and the tunnel width direction may be referred to as the left-right direction. Moreover, the wellhead side in the tunnel longitudinal direction may be referred to as the front side, and the face side may be referred to as the rear side.

As shown in FIG. 1, the slide center 1 includes a portal-type carriage 2 that can travel in the tunnel T, and a mold 3 that serves as a barrier plate for molding the inner peripheral surface of the lining concrete C. Yes.
The portal trolley 2 includes a base portion 2a and a column 2b that supports the base portion 2a. A wheel 2c that engages on a rail R laid on the floor surface of the tunnel T is provided at the lower end of the column 2b, and the wheel 2c rolls along the rail R, so that the portal trolley 2 Travels in tunnel T.

  The mold 3 is formed in a circular arc shape substantially along the inner peripheral surface t1 of the tunnel T, and is set so as to cover the inner peripheral surface t1 with a space in a predetermined span range. 3 is formed between the outer peripheral surface 3b of the tunnel 3 and the inner peripheral surface t1 of the tunnel T.

  The formwork 3 includes a formwork panel 3f that molds the inner peripheral surface of the lining concrete C, and a plurality of reinforcing members 3g that reinforce the inner circumference side of the formwork panel 3f. The formwork panel 3f is formed of a plate material having a thickness of several millimeters. The reinforcing member 3g is made of a steel material such as channel steel, and is disposed along the longitudinal direction of the tunnel T.

The formwork 3 includes an upper portion 3c for molding the top end portion of the lining concrete C, a side portion 3d for pivotally connecting to both ends of the upper portion 3c, and a side portion 3d for molding the side wall portion of the lining concrete C, A lower end portion 3e that is rotatably connected to the lower end of the portion 3d and that molds the lower end portion of the side wall portion of the lining concrete C is provided.
The upper part 3c is supported by a plurality of jacks 4 provided on the base part 2a of the portal trolley 2 so as to be vertically movable.

  The side 3d of the mold 3 is connected to the portal carriage 2 by a plurality of jacks 5a provided on the outer surface of the support column 2b, and can be rotated in the width direction by extending or contracting the jack 5a. It has become. Further, the side portion 3d is also connected to a jack 5b supported on the ground. The jack 5b is supported in a state where the lower end portion is fitted into a recess formed in the ground.

Similarly to the side portion 3d, the lower end portion 3e of the mold 3 is connected to the portal type carriage 2 by a jack 6 provided on the outer surface of the support column 2b. Is possible.
As described above, the mold 3 is connected and supported to the portal carriage 2 and the like by the plurality of jacks (support members) 4, 5a, 5b, and 6 provided on the upper surface of the base portion 2a and the outer surface of the support column 2b. By extending and contracting each of the jacks 4, 5 a, 5 b, 6, the entire mold 3 can be moved up and down relative to the portal carriage 2 and the width dimension can be adjusted.

  In the upper part 3c and the side part 3d of the formwork panel 3f, a plurality of openings 3h are formed side by side in the front-rear direction and the left-right direction. Each opening 3h is configured to be openable and closable by a lid 3j. The opening 3h is used for pouring the lining concrete C into the placement space D, for checking the placement state, or for inserting a compacting vibrator (not shown) into the placement space D. It is used for the purpose.

  The placement device of the present embodiment includes a plurality of (two in the illustrated example) concrete pumps PA and PB. Each concrete pump PA, PB is mounted on a vehicle (concrete pump car). The two concrete pumps PA and PB are installed side by side on the wellhead side of the slide center 1 and lining concrete (fresh concrete) is supplied from the concrete mixer 20 respectively. Each concrete pump PA, PB feeds the supplied lining concrete C to the slide centle 1 side via the pressure feed pipes 10A, 10B, and between the inner peripheral surface t1 of the tunnel T and the formwork 3 Pour into the placement space D.

The pressure feed pipes 10A and 10B include main pipes 11A and 11B, branch pipes 12A and 12B branched from the main pipes 11A and 11B, and end pipes 13A and 13B connected to the terminal ends of the branch pipes 12A and 12B. have.
One end of the main pipes 11A and 11B is connected to the concrete pumps PA and PB, and the other end side is disposed inside the mold 3 of the slide center 1. Specifically, the main pipes 11A and 11B include first portions 11A1 and 11B1 extending in the front-rear direction from the concrete pumps PA and PB, and left and right inner sides (center side in the tunnel width direction) from the rear ends of the first portions 11A1 and 11B1. Second portions 11A2 and 11B2 extending to the left and third portions 11A3 and 11B3 extending rearward (face side) from the second portions 11A2 and 11B2 at the left and right centers of the tunnel.

  The third portion 11A3 of the pressure feeding pipe 10A connected to one concrete pump PA and the third portion 11B3 of the pressure feeding pipe 10B connected to the other concrete pump PB are parallel to each other as shown in FIG. It is arranged side by side in the state. The upper and lower third portions 11A3 and 11B3 have different lengths, and the rear end of one third portion 11A3 disposed at the upper position is disposed at the front side of the mold 3 and disposed at the lower position. The rear end of the other third portion 11B3 is disposed on the rear side of the mold 3.

  As shown in FIG. 3, a plurality (two in the illustrated example) of branch pipes 12A and 12B are connected to the rear ends of the third portions 11A3 and 11B3 via branch pipes 14, respectively. As shown in an enlarged view in FIG. 4, the branch pipe 14 is formed in a Y shape, the main pipes 11A and 11B are connected to one junction part 14a, and the branch pipes 12A and 12B are connected to the two branch parts 14b. Has been. The branch pipes 12A and 12B are curved from the branch pipe 14 by about 90 degrees and extend on both sides in the tunnel width direction.

As shown in FIG. 1, each branch pipe 12 </ b> A, 12 </ b> B is provided with a pressure gauge 16 for measuring the pressure of the lining concrete C flowing inside and a flow rate adjusting valve 17 for adjusting the flow rate.
Three end pipes 13A and 13B are sequentially switched and connected to the outer ends of the branch pipes 12A and 12B in the left-right direction. Two of the three end pipes 13A and 13B are inserted into the placement space D through the lower and upper openings 3h provided on the side 3d of the mold 3. The remaining one is connected to an opening 3 h formed at the width direction end of the upper part 3 c of the mold 3. When the lining concrete C is placed in the placement space D, the branch pipes 12A and 12B are switched and connected to the end pipes 13A and 13B in the order of the lower stage, the middle stage, and the upper stage.
In addition, in FIG. 1, the code | symbol of (U), (M), (L) is attached to the upper and lower three end piping 13A, 13B in order from the upper stage side for easy understanding. .

  The flow resistance of the lining concrete C flowing through the pressure feeding pipes 10A and 10B is greatly influenced by the thickness and bending shape of the pressure feeding pipes 10A and 10B, the pressure feeding height of the lining concrete C, and the like. In the present embodiment, as shown in FIG. 1, the left and right branch pipes 12A, 12B branching from the main pipes 11A, 11B and the left and right end pipes 13A, 13B connected to each other have a tunnel width. It is formed in a symmetrical shape with respect to the center of the direction, and is disposed at a symmetrical height. Therefore, the flow resistance of the lining concrete flowing through the left and right branch pipes 12A and 12A and the left and right end pipes 13A and 13B can be made substantially the same.

  In addition, on the left and right sides of the mold 3, the branch pipes 12A and 12B arranged in the front-rear direction have substantially the same shape and are arranged at substantially the same height, although the height on the base end side is slightly different. Further, the end pipes 13A and 13B arranged in the front-rear direction are also arranged in substantially the same shape and at substantially the same height. Therefore, the flow resistance of the lining concrete flowing through the branch pipes 12A and 12B and the end pipes 13A and 13B can be made substantially the same.

  Further, in the third portions 11A3 and 11B3 in the main pipes 11A and 11B, the upper part 11A3 is formed shorter in the front-rear direction than the lower part 11B3. As the lining concrete C is pumped to a higher position, the flow resistance (or the pressure required to flow) also increases, so the third portion 11A3 disposed at the upper level is shortened and the pumping distance by the main pipe 11A is shortened. By shortening, it is possible to reduce the difference in the flow resistance of the lining concrete C from the main pipe 11B including the third portion 11B3 arranged at the lower level.

  The top end portion of the lining concrete C has a plurality of pieces (example shown in FIG. 2) in which the third portions 11A3 and 11B3 of the main pipes 11A and 11B are connected to the opening 3h at the top portion (left and right center portion) of the mold 3. Then, it can be set up by connecting to the four blow-up pipes 15.

  In the above configuration, in order to place the lining concrete C on the inner peripheral surface t1 of the tunnel T, first, the terminal pipes 12A, 12B of the pressure feeding pipes 10A, 10B are connected to the end pipes 13A, 13B (L) is connected. Then, the two concrete pumps PA and PB are driven at the same time, and the two concrete pumps PA and PB are moved to the bottom of the placement space D on both the left and right sides at two locations on the mold 3 via the pressure feeding pipes 10A and 10B. Pour the lining concrete C.

  When the lining concrete C poured into the placement space D rises to the vicinity of the lowermost end pipes 13A, 13B (L), the concrete pumps PA, PB are stopped, and from all the branch pipes 12A, 12B Lower end pipes 13A and 13B (L) are removed and connected to middle end pipes 13A and 13B (M). Further, the lowermost end pipes 13A and 13B (L) are extracted from the opening 3h, and the opening 3h is closed by the lid 3j. After that, again, the two concrete pumps PA and PB are simultaneously driven, and the lining concrete C is poured into the placement space D.

  When the lining concrete C poured into the placement space D rises to the vicinity of the middle end pipes 13A and 13B (M), the concrete pumps PA and PB are stopped and the middle pipes 12A and 12B are connected to the middle pipes 12A and 12B. The end pipes 13A and 13B (M) are removed and connected to the upper end pipes 13A and 13B (U). Further, the middle end pipes 13A and 13B (M) are extracted from the opening 3h, and the opening 3h is closed by the lid 3j. Thereafter, the concrete pumps PA and PB are driven again, and the lining concrete C is poured into the placement space D.

  Even if the lining concrete C poured into the placement space D rises to the height of the upper end pipes 13A, 13B (U), the lining concrete C is continuously poured into the end pipes 13A, 13B. The lining concrete is press-fitted above (U). Then, as shown in FIG. 6, when the lining concrete C rises to the vicinity of the apex of the formwork 3, the concrete pumps PA and PB are stopped, the main pipes 11A and 11B are connected to the blow-up pipe 15, and the formwork is placed. The lining concrete C is driven from the top of 3 to the top end of the tunnel T.

  As described above, in the placing device of the present embodiment, the lining concrete C can be placed simultaneously at the four locations on the front, rear, left and right of the mold 3. Therefore, a load F (see FIG. 1) is applied to the formwork 3 from both sides in the left-right direction by the laid concrete C. Therefore, it is possible to prevent the mold 3 from being eccentric with respect to the left-right direction, and it is possible to place the lining concrete C in a stable state.

  The lining concrete C pumped from one concrete pump PA is simultaneously placed on both sides in the left-right direction on the front side of the mold 3, and the lining concrete C pumped from the other concrete pump PB is It is driven simultaneously on both sides in the left-right direction on the rear side of the frame 3. Therefore, it is possible to place the lining concrete C on the front side and the rear side of the mold 3 substantially equally on the left and right.

  The branch pipes 12A and 12B branched from the main pipes 11A and 11B to the left and right sides are provided with a pressure gauge 16 and a flow rate adjusting valve 17, so that the lining concrete C flows through the left and right branch pipes 12A and 12B. The pressure adjusting valve 17 can be adjusted so that both measured values are the same. Thereby, it becomes possible to place the lining concrete C more evenly on the left and right sides of the mold 3.

In the present embodiment, since the jack 5b (see FIG. 1) supported by the ground is connected to the side portion 3d of the mold 3, the load F is simultaneously applied to the mold 3 from both the left and right sides. However, the load F can be suitably received by the ground.
In the present embodiment, as shown in FIG. 6, the uppermost end pipes 13 </ b> A and 13 </ b> B (U) are lining concrete not only on the lower side but also on the upper side of the connection portion to the mold 3. Since it is configured to blow and cast C (indicated by hatching of the two-dot chain line in FIG. 6), it is possible to place the covering concrete C over a wide range from the end pipes 13A and 13B (U). It can be done, and until the lining concrete C reaches the apex of the formwork 3, the placement state can be inspected and compacted by a vibrator from the opening 3h provided at the apex portion, thereby improving the workability. Can do. In the present embodiment, since the branch pipes 12A and 12B are provided with the pressure gauge 16 and the flow rate adjusting valve 17, the level of the lining concrete C supplied from the left and right end pipes 13A and 13B is determined as the formwork. The flow rate can be adjusted appropriately so as to be the same at the three apexes.

  When the lining concrete C is placed from one place in the front-rear direction of the mold 3 as in the past (for example, see Patent Document 1), the lining concrete C is moved back and forth as shown in FIG. The cement paste C2 out of the material of the lining concrete C spreads in the front-rear direction and flows, and is easily separated from the aggregate C1. On the other hand, in this embodiment, as shown in FIG. 5 (b), since the lining concrete C is simultaneously placed in two places before and after the mold 3, the spread of the lining concrete C in the front-rear direction is performed. And the separation of the material can be reduced.

  In particular, in this embodiment, lining concrete C pumped from different concrete pumps PA and PB is placed in two places on the left and right sides of the mold 3 on the left and right sides of the mold 3, as shown in FIG. As described above, the branch pipes 12A and 12B and the end pipes 13A and 13B arranged in the front and rear are arranged in substantially the same shape and at substantially the same height, so that the flow resistance of the lining concrete C is also substantially the same. It has become. Therefore, it is possible to place the lining concrete C almost evenly at the two front and rear positions of the mold 3, and to suitably prevent the material from being separated as described above.

  In this embodiment, since the two concrete pumps PA and PB are driven simultaneously to place the lining concrete C, the lining concrete is pumped as compared with the case where one concrete pump is used as in the prior art. The amount (supply amount) can be increased. Therefore, the time required for placing the lining concrete C can be shortened. In actual work sites, when the lining concrete C is placed, the formwork 3 is usually removed at a specific time on the next day, so that the time required for placing the lining concrete C is shortened. Thus, the curing time (hardening time) until demolding can be further increased, and the compressive strength of the lining concrete C can be increased.

FIG. 7 is a front view showing a lining concrete placing apparatus according to a modification.
In this modification, the jack 5b connected to the side 3d of the formwork 3 is supported by the rail R, and receives the load F in the left-right direction from the lining concrete C by the rail R. . Further, in order to support the load inward in the left-right direction applied to the rail R, a rod-shaped inner beam member 19 is installed between the left and right rails R. Since other configurations are the same as those of the above-described embodiment, detailed description thereof is omitted.

The present invention is not limited to the above-described embodiments, and can be appropriately modified within the scope of the invention described in the claims.
For example, a plurality of end pipes 13A and 13B in the pressure feeding pipes 10A and 10B may be connected to the branch pipes 12A and 12B via a pipe switching device as disclosed in the prior art (Patent Document 1). Good. By using such a pipe switching device, it is possible to switch the end pipes 13A and 13B in a short time without changing the plurality of end pipes 13A and 13B.

In the above embodiment, two concrete pumps PA and PB are used, but three or more concrete pumps may be used. In this case, a pressure feed pipe (third pipe) may be disposed from each concrete pump toward three or more locations in the front-rear direction of the mold 3.
The third parts 11A3 and 11B3 in the main pipes 11A and 11B do not necessarily have to be arranged at the center in the left-right direction of the mold 3, and the two third parts 11A3 and 11B3 may be arranged side by side. .

1: Slide center (mobile center)
3: Form 10A: Pressure feed pipe 10B: Pressure feed pipe 11A: Main pipe 11A3: Third part 11B: Main pipe 11B3: Third part 12A: Branch pipe 12B: Branch pipe 16: Pressure gauge 17: Flow rate adjustment valve (flow rate adjustment) apparatus)
C: lining concrete D: placement space PA: concrete pump PB: concrete pump T: tunnel t1: inner peripheral surface

Claims (8)

A device for placing lining concrete in a placement space formed between an inner peripheral surface of a tunnel and a formwork,
Multiple concrete pumps that can be driven simultaneously,
Individually connected to each concrete pump, and provided with a plurality of pumping pipes for guiding the lining concrete to the placement space,
The lining concrete placement apparatus, wherein the plurality of pressure feeding pipes are disposed at positions different from each other in the tunnel longitudinal direction and toward both sides in the tunnel width direction.   2. The lining concrete placing device according to claim 1, wherein each of the pressure feeding pipes includes a main pipe extending in a tunnel longitudinal direction in the formwork and branch pipes branched from the main pipe to both sides in the tunnel width direction. .   The lining concrete placement apparatus according to claim 2, wherein the main pipe is arranged in the center of the tunnel width direction in the formwork.   The lining concrete placing apparatus according to claim 3, wherein main pipes of the plurality of pressure feeding pipes are arranged one above the other.   The placement apparatus for lining concrete according to any one of claims 2 to 4, wherein the branch pipe is provided with a flow rate adjusting device for adjusting a flow rate of the lining concrete.   The lining concrete placement apparatus according to any one of claims 2 to 5, wherein the branch pipe is provided with a pressure gauge for measuring the pressure of the lining concrete. A method of placing lining concrete in a placement space formed between an inner peripheral surface of a tunnel and a formwork,
A method for placing lining concrete, characterized in that, by each of a plurality of concrete pumps, the lining concrete is simultaneously placed on both sides in the tunnel width direction at different positions in the tunnel longitudinal direction.   A formwork for forming a placement space for lining concrete between the inner peripheral surface of the tunnel and a pressure feed pipe in the placement device according to any one of claims 1 to 6. A mobile centle, characterized by

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