KR100420502B1 - Pouring pipe apparatus and the ground pouring method of construction - Google Patents

Abstract

An injection tube device and a ground injection method for injecting the injection liquid into the ground to solidify the ground, and for the ground where the ground situation is different for each layer, the most suitable injection for each layer can be simultaneously achieved and the species in the ground It is possible to make three-dimensional simultaneous injection in both directions and transverse directions, thereby shortening the injection air, and furthermore, it is possible to form a stack of cylindrical penetrating solids obtained by penetrating between the soil particles from the cylindrical penetrating source at once. For this reason, the injection of the chemical liquid according to the design can be achieved at all stages, and the penetration source from one discharge port is enlarged to enable continuous injection of a large amount of the injection liquid by low pressure injection. A plurality of independent capillaries 5 each having a discharge port 4 are bound around the binding injection pipe 2 and the binding injection pipe 2 where each of the discharge ports 4 is positioned to be spaced apart from each other in the axial direction. It is provided with a plurality of packers (3) spaced apart in the axial direction, or in addition to having a facade and independent between the pair of packers (3) adjacent to each other in the injection hole (8) and the hole wall (9) The space 10 is formed, and the injection liquid from the discharge port 4 penetrates into the ground 7 through the whole hole wall 9 of this space 10, and is injected. The binding injection pipe 2 may hold the packer injection pipe together with the customs pipe 5. In addition, the sleeve 10 may be filled with the sleeve grout.

Description

Pouring pipe apparatus and the ground pouring method of construction

The present invention relates to an injection tube device and a ground injection method formed by binding a plurality of independent tubules. In particular, for a ground in which the ground situation is different for each layer, the most suitable injection for each layer can be simultaneously achieved. In addition, it is possible to make three-dimensional simultaneous injection in the longitudinal and transverse directions in the ground more, and also to inject from a large circumferential or cylindrical penetrating source. The liquid penetrates into the circumferential shape between the soil particles at low pressure and solidifies. As a result, the injection effect is excellent, the injection air is also shortened, and the injection tube device is economically excellent. It is about ground injection method.

Since the ground usually has different permeability coefficients and gap ratios for each layer, the ground situation is different for each layer. For this reason, the prior 33㎝ each, or every 50㎝ going to change the injection step (stage) purity grout (瞬結 grout) and complete (緩結) double tube rod injection method for injecting grout into alternating, or a cementitious primary injection the After the injection, a double tube double packer process has been used in which the solution type injects the tea injection material.

Furthermore, when injecting a chemical liquid into the ground of such a material, an injection tube such as a double tube having a plurality of discharge ports at different positions in the axial direction is conventionally used, but is not shown. After embedding, an injection agent was introduced from the upper end of the injection tube, and the injection agent was simultaneously injected into the ground from the plurality of discharge ports described above.

In addition, a plurality of the above-described injection pipes are cut and embedded in the ground, and then, sleeve grout or pure grout is filled between the hole wall and the injection pipe, and through the discharge ports of these injection pipes as described above. Injectants have been injected into the ground.

The problem of the conventional injection method mentioned above is demonstrated using FIGS. 19-21. 19 is an explanatory view of a double pipe rod injection method or a rod injection method, in which the injection liquid delivered into the ground 7 through the injection tube rod 20 is basically a spherical diameter corresponding to the diameter ro of the injection tube rod 20. It penetrates into a spherical form from the penetration source 21 of a ball. 22 is a spherical penetrating solid body.

Since the penetrating source 21 described above has a diameter of ro and is extremely small, it is difficult to penetrate between the soil particles at an economical discharge rate of 101 to 201 / min, and is liable to become a pulse injection. And. Even when the grout grout is injected in advance, the grout flows into the vein, and the subsequent injection liquid with a long gelling time is likely to be sent to the vein along the vein gel. Moreover, the injection liquid comes out from the periphery of the injection tube rod like an arrow.

FIG. 20 is an explanatory view of another injection method using an injection tube rod. After inserting the injection rod 20 of FIG. 19 to a predetermined depth in the ground 7 and pulling it up to a predetermined length, the cylindrical penetration source 21 ). This penetration source 21 is a cylindrical space and injects injection liquid from this space. In this case as well, similarly to FIG. 19, the injection liquid exits from the periphery of the injection tube rod 20 in the direction of the arrow, making it difficult to penetrate the predetermined depth.

21 is an explanatory diagram of a double-tubular pleated packer method. This method fills the sleeve grout 23 between the outer shell 12 and the hole wall 9, that is, in the injection hole 8 to cover the outer shell 12 with the sleeve grout 23, Although it is to prevent deviation to the upper side, this method splits the sleeve grout 23, and injects from spherical penetration source ro is the same as the method of FIG. In these processes, the ground improvement such as large-capacity continuous injection, such as liquefaction prevention work, was hardly difficult.

In a normal injection work, the injection hole spacing is about 1.0 m, whereas in the liquid liquefaction prevention work, it is inevitable to make 1.5-4 m. For example, if the injection spacing is set to 2 m forward,

(1) Place the injection pipe at a constant spacing of P = 2m × 2m.

② Injection speed f = 201 / min

③ The improvement area per hole of the injection pipe shall be Ap = 2m × 2m = 4㎡.

④ When the improved soil volume (m3) per stage is set to V = 2m (improved thickness per stage) × 4㎡ = 8m3,

⑤ Injection amount per stage (kl)

Q = Vx (0.35 ~ 0.04) = 2.8㎥-3.2㎥ = 3.0㎥ (average)

(0.35 to 0.04: injection rate)

⑥Injection time per stage

t1 = 3kl ÷ 0.02 kl / min = 150 min

= 2.5 hours (infusion duration)

Must be injected for a long time.

In addition, when the injection hole spacing is set to the forward direction of 4 m,

Ap = 4 m × 4 m = 16 m 2,

The improved volume of one stage is

V = 2m (improved thickness) × 16㎡

= 32㎥,

1 Stage injection volume (kl) is

Q = Vx (0.35-0.40)

= 32 × (0.35-0.40)

= 11.2-12.8kl ≒ 12kl (average),

If the injection rate f = 201 / min,

Injection time per stage

t = 12kl ÷ 0.02kl

= 600min

= 10 hours

Must be injected.

Therefore, it is necessary to enlarge the effective penetration source. In this way, even if a large discharge amount is injected, the injection speed per unit surface area of the penetration source is small, and since it is not clogged as a gel, it is possible to continuously inject a large amount of the injection liquid at low pressure and solidify a wide range of ground. Do.

In order to cope with this problem, the applicant has developed the technique shown in Japanese Patent Application Laid-Open No. 7-300849 and patented by Japanese Patent No. 2852721.

This source patent binds a plurality of tubules for chemical injection and inserts them into the holes drilled in the ground, fills the sealing grout between the tubules and the hole wall, and solidifies the tubing after the sealing grout is solidified. It is to inject the chemical liquid from.

This allows the three-dimensional simultaneous injection into the longitudinal and transverse directions of the ground by varying the customs discharge outlet in the axial direction, which shortens the air and also has the advantage that the process density can be finished as designed. will be.

However, in this source patent, when injected from a plurality of discharge ports in the axial direction at one time, when the sealing grout in contact with each discharge port is broken, it is broken in a straight line along the sewing seat as if the sewing seat of the sewing machine is pulled from side to side. Similarly, the sealing grout breaks continuously from the bottom to the top, thus preventing the sealing grout. Because of this. Injection from all of the discharge ports is avoided at one time, and discharge holes that are not partially injected are made to prevent continuous fracture.

Further, in the above-described source patent, since the periphery of the discharge port of the injection tubule is covered with the sleeve grout, as in FIG. 19, a problem of a small penetration source arises.

Therefore, the object of the present invention is to not only achieve the most suitable injection for each layer at the same time, but also to enable three-dimensional simultaneous injection in the longitudinal and transverse directions in the ground. It also shortens the air, and furthermore, it penetrates through the entire cut hole wall at each stage to increase the effective penetrating source, thereby enabling low pressure injection. Therefore, the chemical liquid injection as designed can be achieved at all stages, and further, preventing liquefaction. To provide a long time continuous injection into a large volume of soil, such as injection, and to provide an injection pipe apparatus and a ground injection method to improve the shortcomings in the known art.

In order to achieve the above object, according to the injection device of the present invention, in the injection pipe device which is inserted into the injection hole cut into the ground, and injects the injection liquid into the ground through the hole wall, a plurality of tubules, And a plurality of packers arranged in such a manner that the discharge ports of the pumps are positioned at intervals in the axial direction, and a plurality of packers arranged in the axial direction around the bundle injectors, and at least one of the packers adjacent to each other. The discharge port is characterized in that located.

Again, in order to achieve the above object, according to the injection tube device of the present invention, in the injection tube device which is inserted into the injection hole cut into the ground, and injects the injection liquid into the ground through the hole wall, a plurality of tubules, A binding injection tube which is to be connected so that these discharge ports are positioned at intervals in the axial direction, and at least one packer arranged around the binding injection pipe, and below the packer, at least one discharge port is located Characterized in

Furthermore, in order to achieve the above object, according to the injection tube device of the present invention, in the injection tube device which is inserted into the injection hole cut into the ground, and injects the injection liquid into the ground through the hole wall, a plurality of tubules, And a binding injection pipe which is formed such that their discharge ports are positioned at intervals in the axial direction. A plurality of first packers arranged in the axial direction around the binding injection tube and the binding injection tube are inserted therein, the outer wall having a discharge port on the outer wall, and the outer wall surrounding the outer wall of the outer wall in the axial direction. A plurality of second packers arranged, wherein at least one discharge port is located between the first packers, and between a pair of first packers adjacent to each other in the exterior, and the exterior interior wall. A first space is formed.

Moreover, in order to achieve the above object, according to the injection tube device of the present invention, in the injection tube device which is inserted into the injection hole cut into the ground and injects the injection liquid into the ground through the hole wall, a plurality of tubules At least one first packer disposed around the binding injection tube, the binding injection tube being inserted therein, A first having a discharge port and at least one second packer disposed around the outer wall of the external view, and below the first packer, at least one discharge port is located and is formed inside the external view The first space is formed between the packer and the exterior inner wall.

In order to achieve the above-mentioned object, according to the ground injection method of the present invention, a plurality of capillary tubes are bound so that their discharge ports are positioned at intervals in the axial direction, and around the binding injection tube, A plurality of bag bodies arranged axially apart from each other, and between the bag bodies adjacent to each other, an injection tube device configured to have at least one discharge port is inserted into an injection hole cut into the ground; And filling the bag with fluid to expand and form a packer, whereby a space is formed between the pair of packers adjacent to each other and the hole wall, and then the injection liquid is discharged from the discharge port. The injection liquid from the discharge port is injected into the ground through the entire hole wall.

In order to achieve the above object, according to the ground injection method of the present invention, a plural capillary tube is bound so that the discharge ports are located at axially spaced apart from each other, and around the bund injection tube, A plurality of bag bodies arranged axially apart from each other, and between the bag bodies adjacent to each other, an injection tube device configured such that at least one discharge port is located is inserted into an injection hole cut into the ground. The filling hole is filled with a sleeve grout, and then the fluid is filled into the bag and expanded to form a packer, whereby a sleeve grout is formed between a pair of packers adjacent to each other and a hole wall. The injection liquid is discharged from the discharge port, and the sleeve grout is broken to inject the injection liquid from the discharge hole into the ground.

Furthermore, in order to achieve the above object, according to the ground injection method of the present invention, a plural capillary tube is bound so that the discharge ports are positioned at intervals in the axial direction, and around the bund injection tube. At least one bag body is disposed, the lower portion of the bag body is inserted into the injection tube device configured to be located at least one discharge port into the injection hole cut into the ground, and filled the fluid to the bag body and inflated A packer is formed, whereby a space is formed between the packer and the hole wall, and the injection liquid from the discharge port is injected into the ground through the entire hole wall of the space.

Furthermore, in order to achieve the above object, according to the ground injection method of the present invention, a binding injection pipe is formed by binding a plurality of fine pipes so that their discharge ports are positioned at intervals in the axial direction, and around the binding injection pipe. An injection tube device configured to have at least one discharge port positioned below the bag body and inserted into an injection tube cut into the ground, and a sleeve grout is filled in the injection hole. Next, the bag is filled with fluid, inflated to form a packer, whereby a sleeve grout is formed between the packer and the hole wall, and then the injection liquid is discharged from the discharge port. It is characterized by injecting the injection liquid from the discharge port into the ground.

Furthermore, in order to achieve the above object, according to the ground injection method of the present invention, an outer appearance of a plurality of second bag bodies arranged in the axial direction around the outer wall is inserted into the injection hole cut into the ground. 2 bags are filled with a curable fluid, expanded, and solidified to form a second packer, thereby forming a second space between the pair of second packers adjacent to each other and the hole wall. An injection tube device is inserted into the outer tube, and the injection tube device is configured to bind a plurality of tubules so that their discharge ports are positioned at intervals in the axial direction from each other, and around the binding injection tube in the axial direction. And a plurality of first bag bodies arranged apart from each other, and configured such that at least one discharge port is located between the first bag bodies adjacent to each other. A chair Luce to the charge fluid, the inflation packer of claim 1, and a pair of the first packer adjacent to each other thereby. After the first space is formed between the exterior inner wall and the injection liquid is discharged from the discharge port, the injection liquid is transferred from the first space through the second space to the whole hole wall or to the second space. It is characterized by injecting the filled sleeve grout into the ground.

Furthermore, in order to achieve the above object, according to the ground injection method of the present invention, a plural capillary tube is bound so that the discharge ports are positioned at intervals in the axial direction, and around the bund injection tube. An injection hole cut into the ground with at least one first packer disposed, an appearance in which the binding inlet tube is inserted, and at least one second packer disposed around the outer wall of the appearance. At least one discharge port is located below the first packer, and a first space is formed between the first packer formed inside the exterior and the exterior interior wall. And forming a second space between the second packer and the hole wall, and discharging the first space through the whole of the hole wall of the second space or by breaking the sleeve grout filled in the second space. It is characterized by injecting the injection liquid from the sphere into the ground.

1 is a cross-sectional view of one specific example of the injection tube device according to the present invention and the ground injection method using the same.

Figure 2 is a cross-sectional view showing a state in which the curing agent is injected into the bag body of the appearance inserted into the injection hole cut into the ground.

3 is a cross-sectional view showing a state in which a curing agent is injected into the bag of the appearance from the bottom to the top, respectively.

4 is a cross-sectional view showing a state in which a second packer is formed on an outer wall of the outer wall of the outer tube for completely injecting the curing agent into the bag;

5 is a cross-sectional view of another injection tube device of the present invention and another ground injection method using the same.

Figure 6 is a cross-sectional view of another embodiment of the injection tube device of the present invention and another ground injection method using the same.

7 is a cross-sectional view of another embodiment of the injection tube device of the present invention and another ground injection method using the same.

8 (a), 8 (b) and 8 (c) are explanatory diagrams showing modifications of the customs according to the present invention, respectively.

9 is an explanatory view of a cross-sectional view of another embodiment of the injection tube device of the present invention and a ground injection method using the same.

10 is a cross-sectional view of one embodiment of the device of the present invention using a sleeve tube.

FIG. 11 is a perspective view of one embodiment of a pedestal used in FIG. 10. FIG.

12 is a cross-sectional view showing an operation of filling a bag with fluid using a sleeve tube.

FIG. 13 is a partially enlarged cross-sectional view of portion A of FIG. 12.

14 is a cross-sectional view of one embodiment of another apparatus using a sleeve tube.

15 is a partially enlarged cross-sectional view of FIG. 14.

16 is a cross-sectional view showing an injection state using a sleeve grout.

Fig. 17 is a flow sheet showing an actual continuous construction example of the present invention.

18 is a modified example using a pump instead of the pressure tank of FIG.

19 is an explanatory diagram of a conventional injection method.

-Explanation of symbols for the main parts of the drawings-

1: injection pipe device 1A: injection pipe device

1B: injection pipe device 2: binding injection pipe

3: packer 3A: first packer

3B: second packer 4: discharge port

5: customs 6A: pedestal

7: ground 8: injection hole

9: hole wall 10: space

10A: first space 11: columnar penetrating solidified body

12: exterior 12A: exterior inner wall

13: outer wall 19: second space

100: packer injection pipe 106: sleeve grout

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail using an accompanying drawing.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an explanatory view of a cross section of one specific example of an injection tube device of the present invention and a ground injection method using the same. 2 to 5 are cross-sectional views of another injection pipe apparatus according to the present invention and another ground injection method using the same.

In FIG. 1, 1 is an injection pipe apparatus which concerns on this invention, Comprising: It consists of a binding injection pipe 2 and several packers 3, 3 ... 3.

The binding injection pipe 2 is positioned so that the plurality of fine pipes 5, 5… 5 having discharge ports 4, 4… 4 at their ends are spaced apart from each other in the axial direction. It adheres with an adhesive agent, water-expanded rubber, etc., and binds it with the band 6, 6 ... 6 on it.

The packer 3, 3 ... 3 is arrange | positioned in multiple numbers by the axial direction around the binding injection pipe 2. As shown in FIG. And these packers 3, 3 ... 3 are at least between the packers 3 and 3 which adjoin each other, ie, between a pair of packers 3 and 3 which adjoin in a vertical relationship as shown in FIG. One discharge port 4 is disposed to be located.

As the packer 3 described above, a packer, a hard packer, an elastic packer, or the like formed by filling an inert gas such as air or nitrogen, a liquid or a curable liquid, and expanding the bag may be used. However, as shown in Fig. 1, preferably, the cement-based grout is pressed into the bag body through an arbitrary tubing of the binding injection pipe 2, and then expanded. The material of the packer can be any fabric, rubber or synthetic resin. If the fluid to be packed into the packer is air or fluid, the binding injection pipe can be easily taken out of the ground after the injection is completed. After that, it is good to solidify by filling the cement solution.

The injection pipe device 1 configured as described above is inserted into the injection hole 8 cut into the ground 7, and then filled with a curable liquid such as cement-based grout through the tubular pipe 5 in the bag body and expanded. To form packers 3, 3... At this time, an independent space 10 is formed between the pair of packers 3 and 3 and the hole wall 9 adjacent to each other in the injection hole 8.

After the curable liquid is cured, the injection liquid is discharged from the discharge port 4, and the injection liquid is penetrated and injected into the ground 7 in the ground 7 through the entire hole wall 9 of the space 10, and the ground 7 ) To form the columnar penetrating agglomerates 11. In addition, by simultaneously injecting the injection liquid from the plurality of discharge ports 4, 4... 4, a stack of columnar penetrating solid bodies 11 is formed at the same time.

In particular, in the present invention, the cylindrical penetrating from the space 10 can be performed simultaneously in a plurality of steps to form a stack of columnar penetrating fasteners 11 at once. For example, in the present invention, the cutting hole diameter of the injection hole 8 is set to 10 cm, the length of the packer 3 is set to 1 m, and the packer 3 is removed from the center of the capillary 5. It shall be arranged at intervals of 2 m in the axial direction. In this case, one injection step is 2 m, and the size of the cylindrical penetrating circle per step (per stage) is 10 cm in diameter and 1 m in length.

In contrast, in the sphere-penetrating source, the surface area of a sphere having a diameter of 10 cm is obtained. Therefore, in the present invention, when the injection liquid is continuously injected in large quantities over a long period of time, such as liquefaction prevention construction, it can be seen that the present invention can continuously infiltrate for a long time with a large discharge amount without low eye pressure. have. The space 10 may be filled with a sleeve grout as described in detail in FIG. 16 to be described later, and the injection grout may be broken to inject the injection liquid into the ground from a discharge port. This application is suitable when the ground is stacked with finely different permeability depending on the layer shape. In this case, since the packer partitions the sleeve, even if it is injected at once from all the injection ports, the sleeve grout does not break like a seizure of the sewing machine to the ground portion.

In the conventional process performed step by step while performing the above-described infiltration step, the injection liquid not only escapes from the gap around the injection tube to the ground portion, but also easily goes to the surface surface direction in which the topsoil is poor clay, so that it is applied to every predetermined layer. It is difficult to perform horizontal penetration of.

However, as in the present invention described above, if the plurality of upper and lower stages are simultaneously penetrated in a columnar shape, the flow is confined to each other by the penetration pressure of each other in the upper layer and the lower layer of the injection liquid, thereby preventing the penetration in the vertical direction. It penetrates into a cylindrical shape in the horizontal direction, and a lamination of a certain columnar penetrating fastener 11 is formed. In the present invention, each step is divided into packers 3 and 3, so that the injection liquid can be injected by selecting the gelation time, injection speed, and injection amount according to the soil layer of each step.

In the application of the present invention, in the case of improving the relatively shallow ground, the injection apparatus shown in Fig. 6 is used. 6 is an explanatory view of a cross-sectional view of another embodiment of the injection device of the present invention and the ground injection method using the same.

In Fig. 6, 1 is an injection device, in which a plurality of tubules 5, 5, ..., 5 are positioned so that their discharge ports 4, 4, ..., 4 are spaced apart in the axial direction. A binding inlet tube 2 as shown in FIG. 1, which is fixed to a pedestal and bound by a band 6, and at least one packer 3 arranged around the bracket is provided.

The injection pipe device 1 described above is thus inserted into the injection hole 8 cut into the ground 7. The packer 3 is formed by inserting cement-based grout into a bag (not shown) through an arbitrary tubing 2 and then expanding and solidifying it into the ground 7. At this time, at least one discharge port 4 is located below the packer 3, and a plurality of discharge ports 4, 4. Therefore, in the injection hole 8, a space 10 is formed between the packer 3 and the hole wall 9, and the discharge ports 4, 4... Are formed through the entire hole wall 9 of the space 10. The injection liquid from 4) is made to penetrate into the ground 7, and the columnar penetrating solid body 11 is formed.

Then, the injection pipe device 1 of FIG. 6 is inserted into the injection hole 8 cut into the ground 7, and after the sleeve grout is injected into the injection hole 8, the fluid is filled in the bag and inflated. The packer 3 is formed, thereby forming a sleeve grout (not shown) between the packer 3 and the hole wall. Next, the injection liquid is discharged from the discharge port 4, and the sleeve grout is broken to discharge the discharge port. The injection liquid from (4) may be injected into the ground 7. In this case, the injection of the sleeve grout may be injected before the insertion of the injection pipe apparatus 1, and it does not matter even after insertion.

Also, instead of the binding injection pipe 2 of Figs. 1 and 6, an injection pipe having a packer injection pipe that is bound together with a plurality of fine pipes 5, 5, ... 5, and is located in at least a bag packer of the injection pipe. The injection pipe which has a discharge port can be used for the said place. When this example is shown, the binding injection pipe shown in FIG. 10 mentioned below, ie, a packer injection pipe, and the several pipes arranged along the axial direction around the outer wall of this packer injection pipe, It is a binding injection pipe which has a discharge port in the position located in at least a bag packer. In this case, by filling the bag with a fluid from the discharge port and expanding the packer 3 to form the packer 3, the tubing for inflating the bag is unnecessary, and the number of the tubules is reduced. Moreover, the packer injection pipe also serves as a support rod for customs. Details will be described later.

In addition, the sleeve tube may be an injection tube having a discharge port that opens at least in the bag even without a rubber sleeve. In addition, the sleeve tube can determine the injection effect by measuring the water permeability of the ground before and after, and can be injected again if the injection effect is insufficient. In addition, the homogenization of the ground can be measured by performing primary injection of the suspended grout in advance, and the sleeve grout can be filled between the binding tubing and the hole gap by performing the sleeve injection.

In the example of FIG. 6, since the packer 3 does not exist in the lowest part of the binding injection pipe 2, the shape of the penetrating fastening body 11 tends to become semi-elliptical shape. In the injection tube device 1 of FIG. 1, if the lowermost structure is the same as that of FIG. 6, the columnar penetrating and solidifying body 11 of FIG. 1 is formed on the top of the penetration fixing body 11 of FIG. 6. do. When the packer 3 is formed at the bottom of FIG. 6 again, the unit layer of the columnar fastener 11 as shown in FIG. 7 is formed.

The discharge port 4 of the capillary tube 5 used in the present invention is arbitrary, but as shown in FIG. 1, a rubber sack opened by the injection pressure is attached to the distal end, or as shown in FIG. 6. And a plurality of discharge ports 4, 4... 4, which are opened in the tubing 5, may be formed by covering the rubber sleeve 18 so as to have any structure having an effect of reverse displacement. In addition, if the discharge openings 4, 4 ... 4 are formed as pores, the total cross-sectional area of the discharge port is made smaller than the cross-sectional area of the tubule, the internal pressure of the pipe is increased, and the injection liquid is ejected from the discharge port. Infusion liquid is injected at a predetermined speed according to the cross-sectional area.

Furthermore, as shown in FIG. 8 (a), the tubules 5 of the present invention may have two tubules combined into one, and the A fluid and the B fluid may be joined and injected into the discharge port 4 at the distal end portion. As shown in Fig. 8B. Two customs (5, 5) may be combined into one customs (5) on the ground or in the ground to inject the confluence of A and B liquids. As shown in Figure 8 (c). A plurality of discharge ports 4, 4... 4 may be provided near the distal end of one tubule 5.

In addition, the binding injection pipe 2 according to the present invention may be provided with a rod-shaped body (not shown) in the tubules 5, 5. The tubular pipe 5 of the present invention is formed of various materials such as synthetic resin or metal made of nylon, polyvinyl chloride, polyester, or the like. In addition, in the binding injection pipe, a hard rod-like body may be fitted for shape preservation during insertion into a cutting hole. In addition, a sleeve tube attachment outer shell of the double tube double packer method may be inserted in place of the rod-shaped body.

In the present invention, in the case where a thick layer is present in one step, a grout having a relatively short gelling time by the AB confluence liquid is penetrated into the thick layer, and then it is injected into a grout having a long gelling time and injected into a predetermined region. Can penetrate and solidify to a certain size. Of course, you can reinject as needed.

Again, another injection tube device and ground injection method using the same according to the present invention will be described in detail with reference to Figs.

As shown in FIG. 5. Another injection tube device 1A related to the present invention includes a binding injection tube 2 as shown in FIG. 1, a first packer 3A like the packer 3 as shown in FIG. 1, and a binding injection tube 2 therein. It is inserted and provided with the exterior 12 which has the discharge port 17 in the outer wall 13, and the 2nd packer 3B arrange | positioned in the axial direction around the outer wall 13 of this exterior 12, and is comprised. .

In this injection pipe apparatus 1A, first, as shown in FIG. 2, the outer surface 12 in which the plurality of second bag bodies 3C are disposed axially around the outer wall 13 is disposed on the ground 7. ) Into the injection hole (8) cut into the hole.

Subsequently, as shown in FIG. 2, an inner tube 16 having an ejection opening 14 at the tip of the outer opening 12 and having ring-shaped rubber packers 15 and 15 above and below the ejection opening 14. ), The rubber sleeve 18 is pushed through the inner pipe passage 16A and the discharge port 14 from the outer discharge port 17, and the curable liquid such as cement hardener is filled into the second bag 3C. It expands and solidifies and forms the 2nd packer 3B.

Furthermore, as shown in FIG. 3, the inner tube 16 is pulled up to the location of the second bag 3C (shown in FIG. 2) located above, and the cement hardening agent is added to the bag as in FIG. After filling and solidifying, the second packer 3B is formed, and this operation is repeated to form all of the second packers 3B, 3B ... 3B. Then, as shown in FIG. Pull out. At this time, an independent second space 19 is formed between the pair of second packers 3B and 3B adjacent to each other and the hole wall 9.

Then, as shown in FIG. The injection tube device 1B is inserted into the exterior 12. The injection tube device 1B is formed by gluing a plurality of independent tubules 5, 5 ... 5 having discharge ports 4, 4 ... 4 so that each discharge port 4, 4 ... 4 is spaced apart from each other in the axial direction. It is arranged in close contact with the back, or fixed with a pedestal, and axially spaced around the binding injection pipe 2 and the binding injection pipe 2 which are tightly fastened by bands 6, 6... A plurality of first bag bodies (not shown) are provided, and at least one discharge port 4 is disposed between the first bag bodies adjacent to each other. Again, the first bag is filled with air, a liquid, a fluid which is inert gas such as nitrogen, and the like through the tubing 5, and is expanded to form the first packer 3A.

As a result, the 1st space 10A which is independent between a pair of 1st packer 3A, 3A which adjoins mutually, and 12A of exterior walls is formed. Subsequently, the injection liquid is discharged from the discharge port 4, and the injection liquid is circumferentially in the ground 7 from the whole of the hole wall 9 through the second space 19 from the first space 10A. It penetrates and injects and forms the columnar penetrating solid body 11 in the ground 7. The discharge ports 94 and 4. By simultaneously injecting from 4), a stack of columnar penetrating solid bodies 11 is formed at the same time. And, although not illustrated. In the second space 19, sleeve grout is filled in the same manner as in FIG. 16, the isol grout is broken and injected into the ground, and the same effect as in FIG. 16 can be obtained. In addition, the sleeve grout may be filled in the 2nd space at the time of finishing.

Again, in the present invention, when improving the shallow ground, the injection pipe apparatus shown in Fig. 9 is used. 8 is a cross-sectional view of another embodiment of the injection tube device related to the present invention and a ground injection method using the same.

In Fig. 9, 1A is an injection tube device, in which a plurality of fine tubes 5, 5, ..., 5 are bound so that their discharge ports 4, 4, 4 are positioned at intervals in the axial direction (2). ), At least one first packer 3A disposed around the binding injection pipe 2 (which forms the injection pipe device 1B), and the binding injection pipe 2 therein; That is, it is comprised with the external appearance 12 into which the injection pipe apparatus 1B is inserted, and the at least 1 2nd packer 3B arrange | positioned around the outer wall 12A of this external appearance 12. As shown in FIG.

This injection tube device 1A first inserts the external appearance 12 into the injection hole 8 cut into the ground 7 and then the second periphery around the outer wall of the external appearance 12 by the method shown in FIGS. It forms in the packer 3B, and then, the injection pipe | tube apparatus 1B is inserted in the exterior 12, and the 1st packer 3A is formed through the tubule 5.

At least one discharge port 4 is located below the first packer 3A. In particular, in FIG. 9, a plurality of discharge ports 4, 4... 4 are located and covered with rubber sleeves 18, respectively.

A first space 10A is formed between the first packer 3A formed inside the exterior 12 and the exterior inner wall 12A, and again in the injection hole 8 with the second packer 3B. A second space 19 is formed between the hole walls 9, and the injection liquid from the first space 10A is transferred through the entire hole wall 9 of the second space 19. It penetrates and inject | pours into the ground 7, and forms the columnar penetrating solid body 11. As shown in FIG. Although not shown in this case, the sleeve grout is filled in the second space 19, the sleeve grout is broken and injected into the shell, and the effect as shown in Fig. 16 can be achieved. The sleeve grout may be filled in advance in the second space.

In the injection tube device 1A of FIG. 9, since the second packer 3B does not exist at the lowermost end of the injection tube device 1B, the penetration into the downward portion is not constrained. It tends to be semi-elliptical. And by making the structure of the outermost bottom part of FIG. 5 into the structure shown in FIG. 9, it is also possible to set it as the structure which laminated | stacked the columnar-permeable solidified body 11 of FIG. 5 on the solidified body 11 of FIG.

In the present invention, as shown in Fig. 10, as the binding injection pipe 2, the packer injection pipe 100, which is bound together with the plurality of fine pipes 5, 5, ... 5, is used. At least a portion having a discharge port 4A may be used at a position located in the bag packer 100. As an example, for example, as shown in FIG. 10, a packer injection pipe 100 and a plurality of customs pipes 5 arranged along the axial direction around the outer wall 100A of the packer injection pipe 100 are arranged. It is also possible to use the binding injection pipe 2 which becomes.

The plurality of customs pipes 5 are arranged and held around the outer wall 100A of the packer injection pipe 100 by, for example, a collar-shaped pedestal 6A shown in FIG. 11. In other words, the packer injection pipe 100 is fitted into the hole 101 at the center of the plurality of pedestals 6A, and the tubules 5, 5, are provided in the plurality of small holes 102 opened to surround the hole 101. By inserting 5 ... 5), as shown in FIG. 10, several fine pipe | tube 5 is arrange | positioned around the outer wall 100A of the packer injection pipe | tube 100, and is hold | maintained. Then, the bag 3C is provided between the pedestals 6A and 6A adjacent to each other at intervals above and below the binding injection pipe 2 to form the injection pipe device 1. The packer injection pipe 100 has a discharge port 4A covered with a rubber sleeve 18 at least at a position located in the bag body 3C. Such a pedestal can be used to assemble the binding capillary of the present invention with or without a sleeve tube.

As shown in FIG. 12, the injection tube device 1 configured as described above is first inserted into the injection hole 8 of the ground 7, and then the inner tube 103 is inserted into the packer injection tube 100. do. The inner tube 103 has a discharge port 105 at a position to be fitted to the packers 104 and 104 that are winged up and down on the side wall of the tip portion.

Then, as shown in Fig. 12, the tip of the inner tube 103 is aligned with the lowermost bag 3C, and then the fluid is filled from the discharge port 4A through the inner pipe 103 in the bag 3C. The bag 3C is expanded to be a packer 3. Again, the inner tube 103 is pulled up, the tip portion is aligned with the next bag 3C, and the packer 3 is similarly formed to be the injection tube device 1 shown in FIG. FIG. 13 is a partially enlarged cross-sectional view of the portion of FIG. 12, illustrating a packer formation state. FIG.

In the injector 1 of the present invention described above, the filling of the fluid into the bag 3C can be performed through one packer injection pipe 100, and the bag 3C as shown in FIG. No customs 5 is required, so the number of customs 5 can be reduced.

Again, since the tubing 5 is easy to loosen, installation in the injection hole 8 is difficult, but by the use of the packer injection pipe 100, this also serves as a supporting rod of the tubule 5, whereby the injection pipe device Installation in the injection hole 8 of (1) is performed correctly.

And as shown in FIG. 14, the packer injection pipe | tube 100 is not only in the inside of the packer 3, but also in the place located between the packer 3 and the discharge port 4A covered with the rubber sleeve 18. As shown in FIG. Any number can be installed. By using the apparatus of Fig. 14 as described above, after the injection is completed, the injection effect can be confirmed without performing the permeation test of the injection ground through the packer injection pipe 100. If the injection effect is insufficient, as shown in FIG. 14, the inner tube 103 may be installed at a predetermined position to be injected, and may be re-injected through the inner tube 103. FIG. 15 is a partially enlarged view of a portion B of FIG. 14 and shows an injection state easily.

Fig. 16 shows a sleeve grout 106 between a pair of packers 3 and 3 adjacent to each other and the hole wall 9, and breaks up the sleeve grout so as to ground the injection liquid from the discharge port 4 (7). This is an example of injecting in In this case, after injecting the sleeve grout 106 into the injection hole 8, the injection tube device 1 is inserted or the sleeve grout 106 is injected after the injection tube device 1 is inserted. The bag 3C is then filled with fluid, inflated to push out the rib grout 106 into a packer 3, thereby forming a sleeve grout 106 between the adjacent packers 3 and 3. do. Next, the injection liquid is discharged from the discharge port 4, the sleeve grout 106 is broken, and the injection liquid is injected into the ground 7 from the discharge hole 4.

In the injection of FIG. 16, when the soil layers between the upper and lower packers 3 and 3 seem to change small, the soil layers can be injected into the soil layers small. In this case, since the packers 3 and 3 exist on the top and bottom of the sleeve grout 106, even if the injection liquid is injected from the upper and lower discharge ports 4 and 4 into the sleeve grout 106, the sleeve grout 106 is the sewing seat of the sewing machine. There is no accident such as breaking the packer vertically to the ground and losing the packer effect.

17 shows an embodiment of an actual construction example related to the present invention. In FIG. 17, a plurality of injection pipe devices 1 are inserted into a plurality of injection holes 8 cut into the ground 7, respectively. Next, the first solidified layer on a continuous plane is injected from the plurality of injection devices 1, 1... 1 by injecting the injection liquid into the same depth step, for example, the first injection step layer at once. 1 injection step layer), and again, the injection is continued in the same manner below the first solidification layer to form a second injection step layer, and the injection is repeated to solidify the ground 7 as a laminate of planar solidification layers. do.

That is, as shown in Fig. 17, in the present invention, the injection liquid penetrates in the transverse direction at one time in the step of the transverse step of the ground, thereby obtaining a planar solidified body. Next, it is injected in the transverse direction at once from its downward discharge port in the same manner to obtain a planar solidified body. In this way, the injection liquid does not come upward by stacking the planar solidified body.

Such a laminated solid body can be formed in a continuous operation as shown in FIG. In other words, the injection liquid is prepared by the mixer 107 and introduced into the pressurized tank 109 pressurized by the compressor 108. In the pressurizing tank 109, the injection liquid 110 is pressurized by the pressurizer 111 from the compressor 108. The pressure in the pressure tank 109 is measured by the pressure gauge 119. Next, the pressurized injection liquid 110 passes through the pressure gauge 112 and the flow meter 113, and the valve 114, the nozzle 115, the flow meter 116, and the pressure gauge 117 of each injection pipe device. Through each, it is press-fitted into the injection pipe apparatus 1, 1 ... 1 inserted in the injection hole 8 in the ground 7, and is injected in each layer from the discharge port which is not shown in figure, and forms the laminated body.

This operation is automatically performed by the controller 118. That is, as shown in Fig. 17, each mechanical element, that is, the mixer 107, the compressor 108, the pressure tank 109, the pressure gauge 112, the flow meter 113, the valve 114, the nozzle 115 Each element of the flowmeter 116 and the pressure gauge 117 is connected to the controller 118, and these elements are automatically controlled by the controller 118, and an injection operation is performed automatically.

FIG. 18 is a modification of the apparatus of FIG. 17, in which a pump 120 is used instead of the pressure tank 109 of FIG. 17. In this case, the injection liquid in the mixer 107 is introduced into the pump 120, pressurized by this pump pressure, and then press-injected and injected into the injection pipe apparatuses 1, 1. And a laminate of solidified bodies is formed in the same manner as in FIG. 17.

The present invention described above has the following effects.

(1) Since a plurality of capillaries are bundled so that the discharge ports are positioned at intervals in the axial direction, the most suitable injection for each layer can be simultaneously achieved for the ground having different ground conditions for each layer. Furthermore, three-dimensional simultaneous injection in the longitudinal and transverse directions in the ground is also possible. For this reason, the injection work is also shortened.

(2) It is possible to form a stack of columnar penetrating solids obtained by penetrating between cylindrical particles from a cylindrical penetrating source at one time.

(3) The injection liquid is injected through the space formed between the adjacent pair of packers and the hole wall, so that the injection liquid penetrates into the ground from the entire hole wall, so that the source of penetration from one discharge port Large, low pressure injection is possible. Therefore, by continuously injecting a large amount of the injection liquid at a large discharge amount, such as liquefaction prevention work, it is possible to rapidly improve the large-scale soil.

Claims (16)

In the injection pipe device inserted into the injection hole cut into the ground, the injection pipe device for injecting the injection liquid into the ground through the hole wall, a plurality of fine pipes are bound so that their discharge ports are positioned at intervals in the axial direction And a plurality of packers disposed in the axial direction around the binding inlet pipe , wherein the discharge port is located in the packer at the same time as placing at least one of the packers adjacent to each other. After filling and expanding the fluid at the discharge port to form a packer, the injection liquid is injected into the ground at the same time through the plurality of capillary discharge ports, thereby achieving optimum injection for each layer at the same time for the ground with different ground conditions. Injecting apparatus, characterized in that at the same time to form a column-shaped penetrating binder . delete delete delete In the injection pipe device inserted into the injection hole cut into the ground, the injection pipe device for injecting the injection liquid into the ground through the hole wall, a plurality of fine pipes are bound so that their discharge ports are positioned at intervals in the axial direction And a first packer disposed in a plurality of axial directions around the binding injection pipe , the external appearance of the binding injection pipe being inserted therein and having a discharge portion on the outer wall, and axially separated around the outer wall of this external appearance. A first space having a plurality of second packers disposed between the first packers adjacent to each other, wherein at least one discharge port is located and formed inside the exterior, and the first interior packer and the exterior interior wall. The first packer is a packer formed by filling and expanding the fluid in the bag, the second packer is filled, inflated, and solidified by filling the curable fluid in the bag And a packer formed, whereby the ground situation simultaneously achieves optimum injection for each of these layers with respect to the ground in which each layer is different, and a columnar form simultaneously forms a penetrating solid binder . delete delete A plurality of capillary tubes comprising a binding injection tube which is formed such that their discharge ports are positioned at intervals in the axial direction from each other , and a bag body disposed in plural in the axial direction around the binding injection tube; Inserting an injection tube device configured to be positioned between the adjacent bags and at the same time within the bag , into an injection hole cut into the ground, and filling the bag with fluid from a discharge port located at the center thereof ; expansion by and with packer, a space between the pair of packer, and a hole wall which are adjacent to each other by the and injecting the injection liquid from the discharge opening throughout the hole in the wall of the space at the same time the ground, and thereby Thus, for the ground where the ground conditions are different for each layer, optimum injection is achieved for each of these layers at the same time, and column-shaped penetrating solids are formed. Ground injection method, characterized in that formed at the same time . delete A plurality of capillary tubes comprising a binding injection tube which is formed such that their discharge ports are spaced at intervals in the axial direction, and a bag body which is arranged in plural in the axial direction around the binding injection pipe, wherein the discharge ports are adjacent to each other at least one between said chair Luce position Sikkim and at the same time the bag filled at the same time, the sleeve grout the injection hole to insert into the injection hole sakgong the injection piping systems constructed in the ground so as to also position the body, the chair the next Luce that The fluid is filled at the discharge port located in the center and expanded to form a packer, thereby forming a sleeve grout between a pair of packers adjacent to each other and a hole wall, and then discharging the injection liquid from the plurality of capillary discharge ports. and wake up the sleeve grout injected into the injection liquid from the discharge port at the same time the ground and this ground conditions by the A ground injection method characterized by simultaneously achieving optimal injection for each of these layers for different ground for each layer, and simultaneously forming columnar penetrating solids . delete delete Around the outer wall, an outer surface in which plural second bags are disposed in the axial direction is inserted into an injection hole cut into the ground, and the second bag is filled with a curable fluid, expanded, and solidified to provide a second packer. In this way, a second space is formed between the pair of second packers adjacent to each other and the hole wall, and then an injection tube device is inserted into the external appearance, and the injection tube device receives a plurality of tubules. And a binding injection tube which is formed such that these discharge ports are positioned at intervals in the axial direction, and a plurality of first bag bodies arranged in the axial direction around the binding injection tube and adjacent to each other. At least one said discharge port is comprised between the said 1st bag, and it fills a fluid in these 1st bag, and expands it, and it is set as a 1st packer, Thereby, a pair of 1st packer adjacent to each other. After forming the space of the first between the exterior wall, to discharge the injection liquid from said discharge port, and at the same time injecting the injection liquid to soil the from the current hole wall through the space 2 from the space of the first, whereby A ground injection method characterized by simultaneously achieving optimum injection for each of these layers with respect to the ground in which the ground conditions are different for each layer, and simultaneously forming columnar penetrating solids . A binding inlet pipe which is configured to bind a plurality of tubules so that their discharge ports are spaced apart in the axial direction, a first packer disposed in plural axially around the binding inlet pipe, and the binding injection therein between the exterior which tube is inserted, a packer of the first to insert the injection piping system comprising a packer for the second arrangement of a plurality around the outer wall of the appearance in the injection hole sakgong the ground, and close to each other, at least one The discharge port is located, and at the same time, a first space is formed between the first packer formed inside the exterior and the exterior interior wall, and again a second space between the second packer and the hole wall in the injection cavity. forming spaces and, at the same time during the injection of the infusion liquid from the discharge port of the first of the first hole through the entire wall of the space of the second space, ground, and thereby the ground situation relative to the other by the ground on each floor Soil injection method, characterized in that to achieve optimum injection at the same time for each layer, forming a penetration in the circumferential and connective Mo amount at the same time. Claim 13 or according, soil injection method for injecting a liquid from the second space, the sleeve and grout filled, the first space characterized in that the injection in the soil, breaking the sleeve grout according to claim 14. delete