JP2000282791A - Tunneling method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a tunneling method which can reuse excavated soil as concrete without constructing a special plant on the ground, can easily adjust the amount of excavated soil for construction of the concrete, and further can reuse excavated soil generated in a mud shield method. SOLUTION: A mud shield method for carrying out excavation and concrete placement in a tunnel pit 22, comprises an excavated soil carrying-out step of carrying excavated soil to the outside 20 of the tunnel pit, an excavated soil introducing step of introducing part of the excavated soil in a mixer 8 in the tunnel pit 22, a hardener charging step of charging a harder in the mixer 8, and a kneading step of kneading the excavated soil and the hardener in the mixer 8, by the same. The excavated soil carrying-out step corresponds to a step of carrying the excavated soil to the outside via soil conveying pipes 4, 5 of two systems, and the excavated soil introducing step corresponds to a step of introducing the excavated soil in the soil conveying pipe 5 to the mixer 8, by operating a switching valve 6 provided for the soil conveying pipe 5.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tunneling method for performing excavation and concrete placement in a tunnel.

[0002]

2. Description of the Related Art In a tunnel construction method, for example, a tunnel is constructed by using a shield excavator that supports a soil pressure with a large steel cylinder and rotates a cutter face plate on a front face in order to construct a tunnel in soil. There are various construction methods, such as a digging shield method and a renovation method in which concrete is cast after crushing the inner wall of an aged tunnel (for example, the invert portion). Also, there are various shield methods such as a muddy water pressure shield method and a mud pressure shield method. The muddy pressurized shield method uses a pump to pump muddy water from the ground into the excavation room of the shield machine, pressurize the groundwater with muddy water pressure, stabilize the face, and return the cut soil to the outside of the tunnel by returning the muddy water. It is a construction method to discharge to.

In the mud pressure shield method, a cutter chamber of a shield machine is filled with, for example, soil having fluidity and water impermeability, and the relationship between the amount of excavated soil and the amount of earth removed is appropriately controlled. The inside of the cutter chamber is pressurized by appropriately injecting the mud material and stabilizing the face, and the discharged soil is discharged by, for example, a screw conveyor, fed through a conveying pipe, and discharged out of the tunnel pit.

By the way, many technologies have been developed and put into practical use for producing concrete by using excavated earth and sand (soil and sand containing a large amount of mud) generated by a slurry pressurization shield method and using it as an invert material. . Concrete production using excavated earth and sand in the construction of the muddy pressure shield method is generally performed by installing a dedicated plant on the ground and introducing the excavated earth and sand taken out of the tunnel mine into this dedicated plant. However, in many cases, for example, at a construction site in an urban area, a yard (land) for setting up the above-mentioned dedicated plant cannot be secured, and there has been a problem that concrete production using recycled excavated soil cannot be performed.

[0005] Therefore, it is desired to develop a technique for producing concrete by reusing excavated earth and sand in a tunnel.
Conventionally, a technique for reusing excavated earth and sand generated in a tunnel pit as an aggregate in the tunnel pit is disclosed in, for example,
Shielding method disclosed in Japanese Unexamined Patent Publication No.
No. 2,660,096 discloses a method of manufacturing an invert in a shield tunnel. The above-mentioned shield method (Japanese Patent Application Laid-Open No. 2-190600) excavates a stratum not containing much moisture, sieves excavated soil containing no moisture, and classifies and separates soil having a predetermined particle size or more as aggregate. To use. In the production of concrete, a hardening material such as cement is stored in advance in a pit, and the cement and the excavated earth and sand are stirred and mixed to produce concrete.

[0006] The above-mentioned method of manufacturing an invert in a shield tunnel (Japanese Patent Application Laid-Open No. 2-266096) is based on a muddy pressurized shield method, in which a piece of sand having a predetermined particle size or more is placed in the middle of one pressure pipe for carrying out excavated earth and sand. A classifying device for classifying and separating is interposed, and sediment having a predetermined particle size is taken out of muddy soil and used for aggregate. Further, for the production of concrete in the pit, a hardening material tank containing cement or the like is previously loaded into the tunnel pit, and the aggregate and the cement or the like in the hardening material tank are kneaded to produce concrete.

[0007]

However, the above-mentioned conventional shield method for producing concrete by recycling excavated earth and sand in a tunnel pit (Japanese Patent Laid-Open No. 190600/1990).
In Japanese Patent Application Laid-Open No. 2-266096, there is only one system for carrying out the excavated earth and sand, and the timing for performing concrete production or not, the case for producing a large amount of concrete, and the case for producing a small amount of concrete. However, there is a problem that a fixed amount of earth and sand is generated for concrete production, and it is difficult to adjust the amount. In the above-mentioned conventional shield method in which concrete is manufactured by reusing excavated earth and sand in a tunnel pit, cement as a hardening material is stored in the tunnel pit in advance, and concrete is manufactured using the stored cement. In other words, cement (hardening material) needs to be stockpiled for a long time, so that the cement is limited to a powdery one to which water is not added, and ready-mixed concrete or mortar cannot be used because it hardens. Therefore, it was necessary to accurately measure and control the input amount of cement, the input amount of water, and the input amount of aggregate in the mine, and the operation was complicated and complicated.

In the above-mentioned conventional shield method in which concrete is manufactured by reusing excavated soil in a tunnel pit, the excavated soil is not reused as it is, but sediment having a particle size to become an aggregate is obtained from the excavated soil. Use after classification and separation. Therefore, the reuse rate of excavated earth and sand is not so high, and in the shield method in which the excavated earth and sand is carried out through a pumping pipe, separation and classification are difficult to be performed. For example, Japanese Unexamined Patent Publication No. 2-266096 discloses a shield method. Such a large classifier was required.

Conventionally, concrete production using excavated sediment discharged outside the tunnel pit is limited to sediment containing a large amount of muddy water generated by the muddy pressure shield method, and excavated sediment generated by the mud pressure shield method. Concrete production using (for example, excavated earth and sand having water blocking property and fluidity) has not been put to practical use, and research and development thereof have been desired.

An object of the present invention is to provide a tunnel construction method capable of reusing concrete as excavated earth and sand without classifying and separating the excavated earth and sand, in view of the above situation. The amount of excavated sediment used for concrete production can be easily adjusted regardless of the progress, and the control of the mixing ratio of hardened material is not so difficult. The purpose is to provide a tunnel construction method that can be reused.

[0011]

Means for Solving the Problems In the description of the following means, a configuration corresponding to the embodiment will be exemplified by angle brackets as an example. In the case where the same words as those in the embodiment are used, only symbols are described. In order to solve the above-mentioned problem, the invention according to claim 1 is directed to a tunnel construction method in which excavation processing and concrete casting are performed in a tunnel pit [22]. A step of carrying out the excavated matter to be carried out, a step of introducing a part of the excavated matter into the mixer [8] in the tunnel [22], a step of injecting a hardened material into the mixer [8], and a mixer [8] The excavating method includes a kneading step of kneading the excavated matter and the hardened material put in the mixer with a mixer [8], and a concrete placing step of placing the kneaded concrete in a pit [22]. The unloading step is a step of unloading the excavated matter to the outside of the tunnel mine [above ground 20] via a plurality of systems of transport means [sediment pressure pipes 4, 5], and the excavated matter introducing step is performed by the plurality of systems. By operating a switching means [switching valve 6] provided in at least one of the feeding means, the excavated material of the at least one conveying means [sediment pressure feeding pipe 5] is introduced into the mixer [8]. And

According to the first aspect of the present invention, a plurality of transporting means are used to carry the excavated material out of the tunnel mine, and the excavated material is introduced into the mixer from one of the transporting means. Therefore, the amount of excavated material introduced into the mixer can be easily adjusted regardless of the total amount of excavated material. That is, when it is desired to reduce the amount to be introduced into the mixer, it is possible to cope with keeping the total transport amount constant by increasing the transport amount of the transport means of another system. The reverse is also true. Also, in general, concrete is cast in tunnel tunnels.
It is often limited to only a predetermined period, not always. Therefore, in the present invention, the transport destination of the excavated material can be switched between the mixer and the outside of the tunnel by the switching means, so that the excavated material is transported to the mixer only when the concrete is produced by operating the mixer, and when the concrete is not produced, the transport is performed outside the tunnel. Can be carried out. The tunnel method is mainly a shield method that excavates a tunnel with a shield excavator. The tunnel construction method is also included.

[0013] The invention according to claim 2 is a method according to claim 2, wherein
2] In the tunnel construction method in which the excavation process and the concrete placement are carried out in the tunnel excavation process, the excavated material generated by the excavation process is carried out to the outside of the tunnel pit [20 above the ground], and a part of the excavated material is placed in the tunnel pit [22]. And a hardening material loading process of loading a fluid hardening material (for example, ready-mixed concrete or mortar) from the outside of the tunnel [20 above the ground] to the inside of the tunnel [22]. And a hardening material injecting step of injecting the fluid hardening material into the mixer [8], and kneading the excavated material and the fluid hardening material placed in the mixer [8] by the mixer [8]. Process and kneaded concrete in the pit [2
2) and a concrete casting step.

According to the second aspect of the present invention, a fluid hardening material (for example, fresh concrete or fresh mortar) carried from outside the tunnel is used as the hardening material to be injected into the mixer. The time required for kneading is shorter than in the case of kneading from the beginning using water and water, and the management of the mixing ratio of the curing material can be simplified.

According to a third aspect of the present invention, in the tunnel construction method according to the second aspect, the excavated material carrying out step is carried out outside the tunnel via a plurality of systems of conveying means [sediment pumping pipes 4, 5]. In the excavated matter introduction step, switching means [switching valve 6] provided in at least one of the plurality of systems of conveying means [sediment pressure feeding pipes 4, 5] is operated. In this way, the excavated material of the at least one conveying means [the sediment pressing pipe 5] is introduced into the mixer [8].

According to the third aspect of the invention, the operation and effect of the first aspect can be added to the operation and effect of the second aspect. In addition, when a fluidized hardening material is used, if the transport of the hardening material is stopped, the hardening proceeds on the transport path, so that it is difficult to rapidly adjust the supply amount on the hardening material side. Therefore, in the present invention, the introduction amount can be adjusted on the supply side of the excavated material, and thus the mixing ratio of the concrete material can be adjusted appropriately by this adjustment.

According to a fourth aspect of the present invention, there is provided the tunnel construction method according to any one of the first to third aspects, wherein the tunnel construction method is applied to a mud pressure shield method in which excavated soil having fluidity is generated as the excavated material. As the excavated material to be introduced into the mixer [8], the excavated sediment without classification and separation was used.

According to the fourth aspect of the present invention, concrete is manufactured by applying the excavated material as it is to the mixer and kneading it by applying to the mud pressure shield method, so that, for example, a conventional predetermined method is used. Classification of sediment above the particle size
Compared with the method of separating and using aggregates, the reuse rate of earth and sand is better, and no equipment for classifying is required, and the tunnel pit can be widely used. In addition, when using excavated soil of the muddy pressure shield method, it was necessary to use large equipment such as a dewatering device, so it was difficult to produce concrete in the tunnel pit. By applying the same, the excavated soil can be used as it is, so that even when concrete is manufactured in the tunnel pit, there is no inconvenience that the space in the tunnel pit is largely occupied by a device such as a dehydrator.

According to a fifth aspect of the present invention, in the tunnel method according to any one of the first to fourth aspects, the concrete placing step is a step of placing concrete in an invert portion in the tunnel pit [22]. The configuration was adopted. In general, concrete placement in the invert portion is not always performed, but is performed at arbitrary time intervals. Also,
Concrete that is not so high in quality as concrete used for lining tunnel walls can be used.
Therefore, as in the invention of claim 5, claims 1 to 5
The most suitable embodiment is achieved by concrete in the invert part as concrete in which the excavated material of No. 4 is reused.

[0020]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic view showing an embodiment of a tunnel construction method according to an embodiment of the present invention. In the figure, 11 is an inverted material, 20 is the ground, 21 is a standing pile, and 22 is inside a tunnel. As shown in FIG. 1, a shield construction system that implements a tunnel construction method according to this embodiment includes a shield excavator 1, a screw conveyor 2, a rear bogie of the shield excavator 1, or a concrete production place 3 at an appropriate fixed position in a mine. Mixer 8 mounted on the ground, two systems of sediment pressure feed pipes 4 as a plurality of systems of unloading means 4,
5, a switching valve 6 as a switching means, a branch pipe 7 connected to the mixer 8, a concrete feeding pipe 9, a mortar loading feeding pipe 10, a sand hopper 13 for storing excavated earth and sand,
And a truck agitator wheel 14 that conveys a hardening material having fluidity of mortar manufactured at a ready-mixed concrete factory to a site.

The tunnel construction method according to this embodiment is carried out by the above-mentioned shield construction system or the like. While performing tunnel excavation by the mud pressure type shield construction method, a concrete production place 3 in a bogie behind the shield excavator 1 or an appropriate fixed position in the pit. In this method, concrete is produced by reusing excavated earth and sand (excavated material), and the concrete is poured into the invert portion of the tunnel pit 22. Specifically, in this tunnel method, a tunnel excavation process, an excavation earth and sand removal process, and a part of the generated excavation earth and sand are mixed with a mixer 8.
In the excavated matter introducing step, the raw mortar (flowable hardened material) is loaded from the ground 20 and injected into the mixer 8 (the hardened material importing step and the hardened material injection step). It comprises a kneading step of kneading excavated earth and sand and mortar, and a concrete placing step of placing the kneaded concrete in an invert portion.

The tunnel excavation step is a step of excavating a tunnel with the shield excavator 1 by a mud pressure shield method, and the cutter chamber 1B of the shield excavator 1
The cutter chamber 1B is filled with, for example, soil having fluidity and water impermeability, appropriately controlling the relationship between the amount of excavated soil and the amount of earth removed, and appropriately injecting mud material.
The inside is pressurized to stabilize the turning of the face 1A.
The excavated earth and sand in the cutter chamber 1B is discharged to the hopper 2A by the screw conveyor 2. The excavated earth and sand carrying out step is a step of discharging the excavated earth and sand generated by tunnel excavation from the hopper 2A to the ground 20. For discharging, two systems of sediment pressure feed pipes 4, 5 are used, and pumps 4a, 4b, 5a, 5 provided in the middle of the sediment pressure feed pipes 4, 5 are provided.
By the thrust of b, it passes through the inside of the tunnel 22 and the shaft 21 and is carried out to the earth and sand hopper 13 on the ground 20.

In the excavated matter introduction step, one of the excavated earth and sand is generated.
In the step of introducing the part into the mixer 8, by operating a switching valve 6 provided in the middle of the one-system sediment pressure feeding pipe 5, the excavated sediment fed into the sediment pressure feeding pipe 5 is branched into the branch pipe 7. Into the mixer 8. The amount of excavated earth and sand introduced into the mixer 8 can be appropriately adjusted, for example, by adjusting the thrust of the pump 5a and the opening and closing time of the switching valve 6. This introduction process is not always performed,
It is performed only when concrete is poured in the tunnel pit, and at other times, the switching valve 6 is set so that the excavated earth and sand is conveyed to the earth and sand pressure feeding pipe 5 side.

The hardening material carry-in / injecting step is a process of carrying raw mortar (flowable hardening material) from the ground 20 through the shaft 21 into the tunnel pit 22 and injecting it into the mixer 8.
Carrying in is performed via a mortar carrying pressure feeding pipe 10,
On the way, thrust is applied by the pump 10a and the mixer 8
Pumped up to. The mixer 8 is mounted on the bogie behind the shield machine 1 and proceeds with the shield machine 1.
As the process proceeds, the mortar carry-in pressure feed pipe 10 also extends. In the raw mortar, a setting retarder (material) for preventing the hardening from proceeding while the pumping tube 10 is being pumped, a high-performance AE water reducing agent (material) for improving the fluidity during concrete pouring, and a thickening agent An agent (material) such as an agent (material) may be appropriately mixed. This step is not always performed, but is performed only when concrete is cast in the tunnel pit.

The kneading step is a step of kneading the excavated earth and sand and the mortar in the mixer 8. The mixing ratio of the excavated earth and mortar is appropriately controlled according to the soil quality of the excavated earth and sand (for example, a clay-based earth and a soil with a large amount of gravel). For example,
When clay excavated soil (e.g., equivalent to powdered clay) is used, the mortar is 1: 0.8 to 1.2 for sand: cement, 5: 4 to 6 for sand: mortar, and 8 for water: cement. :
By kneading the mixture so as to have a mixing ratio of 9 to 11, concrete having a target strength of 60 kgf / cm ² or more and a viscosity that can be pumped can be produced.

When excavated earth and sand with a large amount of gravel is used, the ratio of sand: cement is 1: 0.8 to 1.2, and the ratio of sand: mortar is 5: 4 to 6, and high performance AE water reducing agent and By adjusting the amount of the thickener to be kneaded, the target strength 6
Concrete having a viscosity of 0 kgf / cm ² or more and having such a viscosity as can be pumped can be manufactured. In other words, by appropriately adjusting the mixing ratio of soil and mortar and the amount of admixture (material) added according to the properties of the excavated soil,
It is possible to produce concrete that can be pumped and achieve the target strength without separation.

The concrete placing step is a step of pumping concrete produced by kneading with the mixer 8 through the concrete pumping pipe 9 and placing it as an invert material 11 in the invert portion of the tunnel pit 22. It is performed intermittently at appropriate time intervals.

As described above, according to the tunnel construction method of this embodiment, two systems of sediment feeding pipes 4 and 5 are used to carry excavated earth and sand to the ground, and one of these two systems is used. Since the excavated material is introduced from the pipe 5 into the mixer, the amount of excavated sediment introduced into the mixer 8 can be easily adjusted regardless of the total amount of excavated sediment. For example, when the excavated earth and sand to be introduced into the mixer 8 is reduced, the total amount of the earth and sand pumping can be made constant by increasing the feeding amount of the other earth and sand pressing pipe 4. In addition, since the transport destination of the excavated material can be switched between the mixer 8 and the earth and sand hopper 13 on the ground 20 by the switching valve 6, the excavated earth and sand is transported to the mixer 8 only when the mixer 8 is operated to perform concrete production. Sometimes it can be carried out of the tunnel pit.

Further, since the raw mortar carried from the ground 20 is used as the hardening material to be injected into the mixer 8, the time required for kneading is reduced as compared with the case where kneading is carried out from scratch using conventional powder cement and water. In addition, the management of the mixing ratio between the hardened material and the excavated soil can be simplified. Also, if the transport of mortar is stopped, the hardening proceeds on the transport path, so it is difficult to adjust the supply amount on the mortar side rapidly, but since the introduction amount is adjusted on the supply side of excavated earth and sand, this The adjustment allows the mixing ratio of the concrete material to be adjusted appropriately.

In addition, since excavated earth and sand of the mud pressure shield method is introduced into the mixer 8 as it is to produce concrete, for example, conventional earth and sand having a predetermined particle size or more is classified and separated and used as aggregate. Compared with the construction method, the reuse rate of excavated earth and sand is good, and a device for classifying is unnecessary, so that the inside of tunnel tunnel 22 can be widely used. In addition, when using excavated mud of the mud pressurized shield method, it is necessary to use a large-sized device such as a dewatering device.
Although it was difficult to produce concrete in Step 2, it is possible to use the excavated earth and sand as it is by applying the method to the mud pressure shield method. There is no inconvenience that the space is occupied greatly.

Further, by laying concrete in the invert portion as concrete laying by reusing excavated earth and sand, an embodiment most suitable as recycled concrete is obtained.

The present invention is not limited to the tunnel method of this embodiment. For example, a shield method, specifically, a mud pressure shield method is given as an example of a tunnel method, but other various tunnel methods are also applicable. May be applied. In addition, as an unloading means for unloading excavated earth and sand, two systems of earth and pressure feeding pipes are illustrated, but more systems may be provided. Although mortar is shown as a hardening material, ready-mixed concrete or the like may be used, and the effect obtained by providing a plurality of conveying means can be obtained even when powder cement is used as the hardening material. Further, the detailed configuration specifically shown, such as the distribution ratio of the hardened material, excavated earth and sand, and water, can be appropriately changed without departing from the gist of the invention.

[0033]

According to the first aspect of the present invention, a plurality of transportation means are used to carry out the excavated material outside the tunnel mine, and the excavated material is transferred from one of these transportation means to the mixer. With the introduction, the amount of excavated material introduced into the mixer can be easily adjusted regardless of the total amount of excavated material. In addition, since the transfer destination of the excavated matter can be switched between the mixer and the outside of the tunnel by the switching means, the excavated matter is transferred to the mixer only when the concrete is manufactured by operating the mixer, and if not, the excavated matter is carried out of the tunnel. You can do it.

According to the second aspect of the present invention, a fluid hardening material (for example, fresh concrete or fresh mortar) carried from outside the tunnel is used as the hardening material to be injected into the mixer. Compared to the case of kneading from scratch with water, the time required for kneading is reduced,
Also, the management of the mixing ratio of the curing material can be simplified.

According to the third aspect of the invention, the effects of the first and second aspects can be combined. Also, if the flow of the hardened hardening material is stopped, the hardening proceeds on the transport route, so it is difficult to adjust the supply amount on the hardened material side rapidly. Adjustment
By this adjustment, the mixing ratio of the concrete material can be adjusted to an appropriate one.

According to the fourth aspect of the present invention, concrete is manufactured by introducing the excavated material of the mud pressure shield method into the mixer as it is, so that, for example, the conventional method of classifying and separating earth and sand having a predetermined particle size or more. Compared to the method used for aggregate, the reuse rate of earth and sand is better, and no equipment for classifying is required, and the tunnel pit can be widely used. Also, when using excavated soil of the mud pressurized shield method, it was necessary to use a large device such as a dewatering device, so it was difficult to produce concrete in the tunnel pit,
By applying the method to the mud pressure shield method, the excavated soil can be used as it is, so that even when concrete is manufactured in the tunnel, there is no inconvenience that the space in the tunnel is largely occupied by a device such as a dewatering device.

According to the fifth aspect of the present invention, the concrete placement of the invert portion is performed as the concrete placement by reusing the excavated material, so that the embodiment most suitable for the recycled concrete is obtained.

[Brief description of the drawings]

FIG. 1 is a schematic view showing an embodiment of a tunnel construction method according to an embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Shield excavator 2 Screw conveyor 3 Rear bogie of shield excavator or concrete production place at an appropriate fixed position in a mine 4, 5 Two-system sediment pressure feeding pipe (unloading means) 6 Switching valve (switching means) 7 Branch pipe 8 Mixer 9 Concrete Pumping Pipe 10 Mortar Carrying Pumping Pipe 11 Invert Material (Concrete Cast Into Invert) 13 Sediment Hopper 14 Truck Agitator Car 20 Ground 21 Standing Pile 22 Inside Tunnel Tunnel

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Shinichi Saida 1-20-10 Toranomon, Minato-ku, Tokyo Inside Nishimatsu Construction Co., Ltd. (72) Inventor Yasuhiko Sato 1-20-10 Toranomon, Minato-ku, Tokyo Nishimatsu Construction Co., Ltd. (72) Inventor Noriyuki Nishida 1-20-10 Toranomon, Minato-ku, Tokyo Nishimatsu Construction Co., Ltd. (72) Inventor Shinichi Kanamaru 1-20-10 Toranomon, Minato-ku, Tokyo Nishimatsu F-term in Construction Corporation (reference) 2D054 AC04 CA05 DA03 DA24 2D055 BA01 CA08 KA08 KA09 KA11 KB00

Claims (5)

[Claims] 1. A tunnel construction method in which excavation processing and concrete casting are carried out in a tunnel pit, wherein an excavated matter is carried out outside the tunnel pit, and a part of the excavated substance is removed from the tunnel pit. Excavated material introduction process for introducing into the mixer, hardened material injecting process for injecting the hardened material into the mixer, kneading process for kneading the excavated material and the hardened material placed in the mixer with the mixer, and mixing the kneaded concrete in the downhole The excavated matter carrying out step is a step of carrying out the excavated matter to the outside of the tunnel mine through a plurality of systems of transporting means, and the excavated matter introducing step includes: By operating a switching means provided in at least one of the plurality of transport means, the excavated material of the at least one transport means is introduced into the mixer. Tunneling method, which is a degree. 2. A tunnel construction method in which excavation processing and concrete casting are carried out in a tunnel pit, wherein a digging object carrying-out step of carrying out the digging substance generated by the digging processing to the outside of the tunnel pit; An excavated matter introducing step for introducing into the mixer; a hardening material carrying-in step for carrying a flowing hardening material into the tunnel from outside the tunnel; a hardening material injecting step for injecting the flowing hardening material into the mixer; A tunnel construction method, comprising: a kneading step of kneading excavated matter and a fluid hardening material put in the inside with a mixer; and a concrete placing step of placing kneaded concrete into a pit. 3. The tunnel construction method according to claim 2, wherein the excavated matter carrying out step is a step of carrying out the excavated matter out of the tunnel mine via a plurality of systems of conveying means. A tunnel method, wherein the excavated material of the at least one transport means is introduced into the mixer by operating a switching means provided in at least one of the transport means of the plurality of systems. 4. The tunnel construction method according to claim 1, wherein the excavation object is applied to a mud pressure shield construction method in which excavated soil having fluidity is generated, and the excavation is introduced into the mixer. A tunneling method characterized by using uncut excavated earth and sand without classification and separation as the object. 5. The tunnel construction method according to claim 1, wherein the concrete placement step includes placing concrete in an invert portion in a tunnel pit.