JPH0941356A - Freezing control method in method of freezing construction - Google Patents

Abstract

PROBLEM TO BE SOLVED: To lower power consumption by improving frozen-soil forming efficiency, and to reduce the cost of the execution of works by lengthening the intervals of the installation of freezing pipes and shortening the length of the installation of the freezing pipes. SOLUTION: In a method of freezing construction, in which freezing pipes 1, 1... are buried into the ground while frozen soil is formed around the freezing pipes by circulating a refrigerant into the freezing pipes 1, 1,..., a flow in the specified direction is generated forcibly to groundwater by pumping up groundwater by a pumping facility 2. Frozen soil 3 is formed by the freezing pipes 1 under the state.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention embeds a freezing pipe in the ground and circulates and supplies a refrigerant into the freezing pipe to form frozen soil around the freezing pipe to form a continuous frozen soil wall and a strengthened region. In the freezing method, the present invention relates to a freezing control method which has the advantages of improving the efficiency of frozen soil formation, reducing construction costs, shortening the construction period, and controlling the formation range to suppress the influence on surrounding structures.

[0002]

2. Description of the Related Art Civil engineering works in urban areas in recent years involve a lot of work on soft ground centering on alluvium, and there are not a few cases where excavation is carried out along a riverbed or along a river. When excavating such a soft ground with a high groundwater level, spring water and accompanying ground collapse phenomenon are likely to occur, and construction is extremely dangerous. As measures against these problems, a ground improvement method and a reinforcement method centering on the chemical injection method have been developed to date.

However, with the chemical injection method, it is impossible to completely solidify the soil and stop the water, and the use of the chemical solution has been restricted from the viewpoint of environmental protection. For these reasons, the freezing method has been receiving attention in recent years as an alternative method to the chemical solution injection method.

In the freezing method, a steel pipe having a diameter of about 10 cm called a freezing pipe is buried in the ground, and a cooling liquid is circulated and supplied to the freezing pipe to continuously cool it at a temperature below the freezing point to artificially ground the ground. This is a freezing method. Frozen soil grows concentrically around the freezing pipe due to long-term cooling, so if the freezing pipes are properly lined up and buried, adjacent frozen soil pillars will merge with each other to create a continuous frozen soil wall or block. Area) is formed. Since the frozen soil wall has perfect water impermeability and great mechanical strength, it will be used as a temporary earth retaining wall or protection wall for civil engineering work.

The freezing method has a number of advantages. Listed below, frozen soil has high strength and can be used as a bearing wall. Frozen soil has low air permeability and water permeability, so it can be used as a barrier against compressed air and as a water barrier. It has a large freezing force and can form a structural wall continuous with steel and concrete. Since the property of heat conduction is utilized, frozen soil walls with uniform strength are formed when frozen, regardless of the heterogeneity of the ground. After the construction is completed, the frozen soil is thawed, so there is no ground contamination or obstacles left, which is effective for environmental protection.

[0006] The freezing method was locally applied to specific works such as riverbed crossing works at the beginning of development, but in recent years, due to its usefulness, subways, water and sewage systems, underground regulating ponds, underground tunnels for gas and electric power, etc. Is frequently applied in. Especially,
With the development of the shield construction method, it has come to be applied as a standard for protection of the starting part, reaching part, sharp curve part, underground joint, wide part, etc. of the shield.

[0007]

However, even the freezing method, which has many advantages as described above, has the following drawbacks due to the characteristics of the method principle. The period until the ground freezes and the frozen soil wall is formed is relatively long. Freeze expansion does not occur in the gravel layer, but in the ground that contains a large amount of fine particles, freeze expansion may occur and dehydration consolidation may occur during thawing, which may affect surrounding structures. Construction costs are high. At present, the above-mentioned drawbacks are greatly affected by the cooling efficiency of the freezing equipment. Therefore, the number of freezing tubes is increased and the laying pitch of the freezing tubes is reduced. Regarding the above-mentioned drawbacks, the freezing range is kept to a necessary minimum, the offsetting of the looseness of the ground due to the boring hole is used, the arrangement of the freezing pipe is examined, and the freeze expansion displacement is matched with the heat flow direction. We are dealing with it by using it. In addition, dehydration consolidation is dealt with by increasing the thawing speed and accelerating the dehydration speed by using a heating tube or the like. With regard to the above-mentioned drawbacks, since power consumption due to continuous operation for a long time and cooling efficiency of freezing equipment are greatly affected, development of a freezing method or equipment having good freezing efficiency is desired.

As a countermeasure for each of the drawbacks,
Although various methods have been proposed or implemented, expansion of construction equipment is required, resulting in an increase in construction cost.

[0009] Therefore, the main object of the present invention is to reduce the power consumption and to increase the installation interval of the freezing tubes so that the frozen soil can be formed in a wide range in a short time, that is, by improving the frozen soil formation efficiency. By reducing the construction cost by shortening the installation length and the installation length, shortening the construction period, and avoiding areas that should not be frozen, such as adjacent private houses, by controlling the frozen area. The present invention proposes a freezing control method having advantages such as being able to suppress environmental problems such as freeze expansion and dehydration consolidation.

[0010]

A first aspect of the invention for solving the above-mentioned problems is to freeze a frozen pipe by embedding a freezing pipe in the ground and circulating a refrigerant in the freezing pipe to form frozen soil around the freezing pipe. In the construction method, the propagation direction of cooling heat diffused from the freezing pipe is controlled by forcibly causing a flow in a predetermined direction with respect to groundwater.

Specifically, there are two types of freeze control method patterns. First, the first method is, in the first invention, a method of growing frozen soil in a rugby ball shape, for example, by maintaining the flow velocity of the flow generated in the groundwater at a freezing limit flow velocity or less.

As a second method, in the first invention, a first control step of controlling the flow velocity of the flow generated in the groundwater to be equal to or higher than a freezing limit flow velocity and expanding an unfrozen low temperature region in a predetermined direction. A freezing control method comprising a second control step of freezing the unfrozen low-temperature region by stopping the flow of groundwater or reducing the flow velocity. This method expands the unfrozen low-temperature region to, for example, a rugby ball shape under conditions of freezing limit flow velocity or more where frozen soil formation is inhibited, and then stops the flow of groundwater or reduces the flow velocity thereof. The shape is frozen.

FIG. 1 shows the principle of the freezing control method according to the present invention.
In the following description, the freezing pipe 1 is inserted and installed in the ground, and the pumping equipment 2 such as a deep well is installed at a predetermined distance. When the water is pumped from the pumping equipment 2, the groundwater flows into the pumping equipment 2,
A hydraulic gradient occurs, and the position of the initial groundwater level W ₀ changes to the groundwater level W after pumping. On the other hand, when a refrigerant is supplied to the freezing tube 1 to cool the freezing tube, the cooling heat diffused from the freezing tube does not spread in the radial direction as in the conventional case,
Since the groundwater propagates in the direction of the pumping equipment 2 depending on the flow direction S, frozen soil is formed in a rugby ball shape at a position eccentric from the freezing pipe 1 as shown in FIG. For reference, the frozen area by the conventional method is shown by a broken line.

Therefore, in the case of freezing to a predetermined width, a circular frozen ground is formed in the conventional case, whereas in the case of the present invention, an ellipse is formed by flowing groundwater in the width direction. Since frozen soil is formed in a uniform manner, the volume of frozen soil as a whole is small and power consumption is low. Further, since frozen soil having an elliptical cross section is formed, the freezing sharing width of one freezing tube can be made large, and the number of installations and the total installation length can be reduced. further,
Since it becomes possible to limit the spread of frozen soil in a predetermined direction, it becomes possible to form frozen soil by avoiding areas that you do not want to freeze, and it is possible to suppress the influence on surrounding structures such as private houses. it can.

On the other hand, a second aspect of the present invention for improving the efficiency of frozen soil formation is to form a frozen soil wall continuous around the frozen tubes arranged at intervals to form frozen soil for each frozen tube. Until the coalescence, the flow of groundwater is generated in the row direction of the freezing tubes, and the frozen control method described above forms frozen soil with an eccentric cross section around each freezing tube, and then each freezing tube The feature is that after the frozen soils generated for each coalesce, the frozen soils are grown with the flow of groundwater stopped.

The freezing control method of the present invention is shown in FIG. 9, in which the vertical axis is the one-sided freezing progress thickness and the horizontal axis is the number of cooling days. This is because the difference in characteristics from the plate growth curve after becoming a continuous wall is used. That is, when the frozen soil grows in an annual ring shape, the increase in the thickness is slow, and since the frozen soil grows quickly after being coalesced into a plate-like shape, until coalesced into an elliptical shape by the freezing control method of the present invention. The frozen soil is grown to accelerate the coalescence period, and to shift to the plate growth curve at an early stage. As a result, it is possible to shorten the number of days required for forming a frozen ground of a predetermined thickness, and it is possible to shorten the construction period as a whole.

In these freeze control methods, the flow of the groundwater can be generated by, for example, pumping the groundwater or pouring water into the groundwater. In addition, the flow velocity of groundwater can be controlled by controlling the amount of groundwater pumped or injected.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail. First, the freezing method will be briefly described. The freezing method includes a brine method and a liquid nitrogen method depending on the difference in the method of cooling the freezing pipe. Of these, the freezing method using the brine method has many construction results and is generally used. Is.

In the brine system, an antifreeze solution called brine (calcium chloride aqueous solution, specific gravity 1.286 and freezing temperature -55 ° C) is cooled to -20 to -30 ° C, and this is sent to a freezing pipe by a circulating water pump. It cools the ground. The brine, which has taken heat from the ground and has risen in temperature, is returned to the freezing unit and cooled. The freezing unit is composed of a compressor, a condenser, a cooler, and the like, and heat in the ground is repeatedly released from the freezing pipe to the atmosphere through brine, cooling water, and into the atmosphere.

On the other hand, in the liquid nitrogen system, liquid nitrogen (boiling point −196 ° C.) carried by a tank truck is poured directly into a freezing tube, and the heat of vaporization cools the ground. The nitrogen gas vaporized by removing heat is released into the atmosphere.

Regardless of which cooling method is adopted, if the cooling liquid is continuously circulated in the freezing pipe, the surrounding ground is cooled from the surface of the pipe, and frozen soil usually grows in an annual ring shape. As shown in FIG. 10, if the freezing tubes 1, 1, ... Are buried at appropriate intervals, the frozen soil columns 3, 3, ... That have grown from the adjacent freezing tubes 1, 1 ,. The continuous frozen soil wall 4 is completed, and thereafter the frozen soil grows in a direction in which the thickness of the frozen soil wall increases. Under standard construction conditions, it takes about 1 month to form a 1.5 m thick frozen soil wall and about 2 months to form a 2 m thick frozen soil.

At the time of construction, it is necessary to know the thermal constants of the saturated soil in the frozen state and the unfrozen state, especially the specific heat and the thermal conductivity. Although it is difficult to know the specific heat and thermal conductivity values of various soils accurately, it is known about water, ice, and soil particles alone, so the soil value as an aggregate is estimated from the mixture ratio. Can be used.

It is also important to estimate the cooling load in advance by grasping the ground temperature distribution in the frozen soil target area and to make the capacity of the freezing unit sufficient.

In any case, when adopting the freezing method, in order to proceed with the construction efficiently, the soil quality of the frozen ground, the physical properties of the target soil, the state of groundwater, the influence on the adjacent structures, and the freezing expansion -It is important to draw up a construction plan while paying attention to each item such as dehydration consolidation prediction and physical strength of frozen soil.

In adopting the freezing control method according to the present invention, since the conventional freezing method system can be used as it is, the device itself will not be described in detail.

An example in which the freezing method of the present invention is applied to the construction of a water blocking wall will be described below. In FIG. 2, the freezing pipes 1, 1 ... Are lined up at intervals on the same line, and the inside of a pipe called a riser pipe installed in the ground is installed at a position substantially separated by a predetermined distance on the line of the freezing pipes. By installing a submersible pump or a pumping equipment 2 such as a deep well for forcibly draining water by installing a submersible pump in the well point or the pumping well by evacuating the groundwater, the freezing pipes 1, 1 ... While circulating and supplying the refrigerant, the groundwater is pumped up from the pumping equipment 2.

Then, as shown in the plan view of FIG.
The flow of groundwater is generated in the row direction of the freezing pipes 1, and the cooling heat diffused from the freezing pipes 1 is propagated in the flow direction of the groundwater. Therefore, frozen soil 3 having an elliptical cross section is formed around each freezing pipe 1 at a position eccentric from the center of the pipe axis in the flow direction of groundwater. For comparison, an example in which the frozen soil 3 is formed without causing groundwater flow is shown in FIG. As is clear from the comparison between FIG. 3 and FIG. 4, in the case of the method of the present invention, the frozen soil 3 is formed into an elliptical shape,
The arrangement interval P of the freezing tubes 1 can be set larger than the arrangement interval P ₀ of the freezing tubes according to the conventional method. According to a trial calculation by the inventors of the present application, P / P ₀ can be set to about 1.2 to 2.

When the groundwater level is lowered due to the pumping of groundwater and there is a concern about ground subsidence, the ground subsidence is suppressed by returning the pumped groundwater back into the ground as shown by the broken line in FIG. You can

Further, as the means for generating the flow of groundwater, the movement of groundwater by the electroosmosis method can be applied. The electroosmosis method is a type of groundwater level lowering method, in which a pair of electrodes is installed in fine-grained soil saturated with water, and when a direct current is applied, the phenomenon that pore water flows to the cathode due to electroosmosis is used. In this method, a steel pipe with a strainer is used as the cathode, and the groundwater flowing to the cathode is forcibly discharged.

Therefore, in this freezing method, an anode is installed on the upstream side where a groundwater flow is desired to occur and a cathode is installed on the downstream side, and a direct current is passed. In this case, pumping is not always necessary. Without pumping up, the flow at the current water level will occur with respect to the groundwater, so ground subsidence due to groundwater drop will not occur.

In the present invention, the means for generating the groundwater flow is not limited to the above embodiment. Any method can be adopted as long as it results in a groundwater flow.

Next, as a second example, FIG. 5 shows an example of freeze protection of the shield starting portion. After constructing the vertical shaft 5 at the shield starting part, the freezing pipes 1, 1 ... are installed around the planned shield excavating part along the tunnel advancing direction, and in order to generate groundwater flow in the tunnel advancing direction, Pumping equipment 2 is installed on the downstream side.

In the case of the second example, since the frozen soil forming region can be extended in the tunnel advancing direction, the installation length of the freezing tube 1 can be shortened as compared with the conventional method.

By the way, in the presence of the flow of groundwater, if there is a flow at a speed higher than a certain speed in the ground to be frozen, it may not be possible to form a frozen soil wall due to the heat carried into it, or a frozen soil once formed. The control of the groundwater flow rate is a very important factor in the present invention because the wall may be thawed by the generation of a new groundwater flow.

Therefore, the mechanism of heat in the ground and the flow of groundwater will be described, and the relation with this freezing method will be mentioned. In the freezing method, the ground around the freezing pipe is cooled with time by the heat generated from the freezing pipe inserted into the ground. Considering the heat propagation in the ground considering the flow of groundwater as a simple one-dimensional unsteady problem, it is shown by the following equation (1). The first item on the right-hand side is the item related to heat conduction, the second item is the item related to advection (groundwater flow), and the third item is the item related to the cooling heat of the freezing pipe, per unit volume when water freezes and changes into ice. As the heat energy of, the latent heat of freezing of 79.5 cal / g is released.

[0036]

[Equation 1]

Velocity V appearing in the second item of equation (1)
Is caused by the flow of groundwater.

Next, the effect of this flow velocity will be examined. Focusing on the mechanism of groundwater flow in the ground, groundwater flows from a higher head to a lower head. The average groundwater velocity at that time is given by the following equation (2) according to Darcy's law.
Represented by

[0039]

[Equation 2]

When the equation (2) is replaced with a general form, the following equation (3) is obtained. Where i is the hydraulic gradient.

[0041]

(Equation 3)

On the other hand, the limit flow velocity at which frozen soil is not formed by the flow of groundwater is called the freezing limit flow velocity, and the following equation (4)
It is represented by As can be seen from equation (4), the freezing limit flow velocity V
The crit increases as the number of frozen tubes increases and the cooling temperature increases, and decreases as the length of the frozen soil wall increases. In case of sandy soil, it is about 1 m / day.

[0043]

(Equation 4)

Therefore, the groundwater flow velocity V for controlling the formation of the frozen soil wall by widening the freezing range of the ground by the advection effect of the cooling heat of the freezing pipe must satisfy the following expression (5).

[0045]

(Equation 5)

As described above, in the first and second examples, the hydraulic gradient i shown in equation (3) is controlled by adjusting the amount of pumping, and the groundwater flow velocity V is set to the freezing limit flow velocity Vcr.
below it, preferably 80 to 90% of the freezing limit flow rate Vcrit
Control by aiming at the flow velocity.

By the way, in the present invention, it is not an essential requirement that the flow velocity V of groundwater be equal to or lower than the freezing limit flow velocity Vcrit. In the first example and the second example, since frozen soil is grown while freezing, control is performed under the condition of groundwater flow velocity V ≦ freezing limit flow velocity Vcrit, but groundwater flow velocity V is equal to or higher than freezing limit flow velocity Vcrit. It is also possible to freeze the water at once by reducing the groundwater flow velocity to 0 or reducing the temperature after expanding the low temperature region while keeping it unfrozen.

[0048] Explaining in detail based on the example of freeze protection in the shield starting portion shown in Fig. 7, in step (I), the freezing pipe 1 is provided in the tunnel starting direction in the shield starting portion,
1 is installed and cooling is performed by supplying a refrigerant, and pumping equipment 2 is installed on the downstream side in the tunnel excavation direction to pump water to generate a predetermined hydraulic gradient i. At this time, the amount of pumped water is controlled so that the groundwater flow velocity V becomes equal to or higher than the freezing limit flow velocity Vcrit.

Next, as shown in step (II), the state of groundwater flow velocity V ≧ freezing limit flow velocity Vcrit is maintained and the unfrozen low temperature region is expanded around the freezing pipes 1, 1 ,. Then, as shown in step (III), pumping is stopped and the unfrozen low temperature region is frozen at once.

On the other hand, the present invention can be used as a measure for shortening the construction period in constructing the water blocking wall. FIG.
As shown in FIG. 8, when constructing the water blocking wall in the area surrounded by the chain lines 7 and 7, the frozen soil generated in each frozen tube is merged, as shown in FIG. 8 (I). Further, according to the present invention, a flow of groundwater is generated in the row direction of the freezing pipes 1, 1, ... And a refrigerant is circulated and supplied to each of the freezing pipes 1, 1 ,. The eccentric frozen soil 3, 3, ... Is formed.

Then, as shown in FIG. 8 (II), after the frozen soils 3, 3 produced for the respective freezing pipes 1, 1, ... Are united, pumping is stopped to stop the flow of groundwater. Freezing tubes 1, 1
The refrigerant is continuously supplied to. Then, the combined continuous frozen soil grows in the thickness direction, and the water blocking wall 4 is constructed in the area surrounded by the chain lines 7, 7.

In the frozen soil growth curve shown in FIG. 9, the present method clearly compares the simple growth curve before adjacent frozen soils are united with the plate growth curve after they are joined to form a continuous wall. As described above, the construction period is shortened by utilizing the fact that the frozen soil that has become a plate has a significantly higher degree of progress in thickness (this fact is known per se). In addition, the difference in the growth rate is that when soil is frozen, the thermal conductivity generally increases about twice as much as before freezing and the specific heat becomes smaller. Therefore, after the frozen soil that has grown around the freezing tube has coalesced. Is estimated to be due to the overall mass effect and the co-cooling effect of each freezing tube.

That is, according to the above-mentioned frozen soil growth curve, it is apparent that the frozen soil has a higher growth efficiency after it has been united into a plate body, so that it is formed around each freezing tube as early as possible. By incorporating frozen soil, it is expected that a water blocking wall of a predetermined thickness can be constructed in a shorter period of time as a result. Therefore, according to the freezing method of the present invention,
By forming frozen soil in an elliptical shape around each freezing tube, the coalescence period can be accelerated, and as a result, the number of days required to form frozen soil of a predetermined thickness can be shortened and the construction period can be shortened as a whole. You can

By the way, the principle of the freezing method of the present invention can be applied to, for example, the usual chemical injection, grout injection and the like. That is, when forming a solidified body or a water blocking wall in the ground by injecting a chemical liquid or grout material, it is possible to expand the solidification range and increase the interval between injection pipes by generating a groundwater flow. it can.

[0055]

As described above in detail, according to the present invention, frozen soil can be formed in, for example, an elliptical cross section or a rugby ball shape, so that compared to the conventional circular frozen soil. It is possible to improve the frozen soil formation efficiency per unit area. As a result, the power consumption can be reduced as a whole, and the construction cost can be reduced by increasing the installation interval of the freeze tubes and shortening the installation length. Also, the construction period can be shortened. Further, by controlling the freezing area, it becomes possible to perform construction in an area such as an adjacent private house that should not be frozen, and it is possible to suppress environmental problems such as freezing expansion and dehydration consolidation.

[Brief description of drawings]

FIG. 1 is an explanatory view of the principle of a freezing control method according to the present invention.

FIG. 2 is a schematic view in which the freezing method of the present invention is applied to construct a water blocking wall.

FIG. 3 is an enlarged plan view of a cryotube placement portion.

FIG. 4 is a diagram showing an example of forming frozen soil by a conventional method.

FIG. 5 is a schematic diagram in which the freezing method of the present invention is applied to protection of a wellhead of a shield starting portion.

FIG. 6 is a function value calculation diagram in Equation 4.

FIG. 7 is a control pattern step diagram according to the freezing method of the present invention.

FIG. 8 is a procedure diagram for constructing a water blocking wall by applying the method of the present invention.

FIG. 9 is a frozen soil growth curve diagram.

FIG. 10 is an explanatory view of a procedure for forming a water blocking wall by a conventional method.

[Explanation of symbols]

 1 ... Freezing pipe, 2 ... Pumping equipment, 3 ... Frozen soil, 4 ... Water blocking wall

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Zensei Shimizu 4-12-20 Nihonbashihonmachi, Chuo-ku, Tokyo Inside Sato Industry Co., Ltd. (72) Noriyoshi Kaneko 4-12-20 Nihonbashihonmachi, Chuo-ku, Tokyo (72) Inventor Hidetaka Nakamura 4-12-20 Nihonbashihonmachi, Chuo-ku, Tokyo Inside Sato Industry Co., Ltd.

Claims (5)

[Claims] 1. A freezing method in which a freezing pipe is buried in the ground and a frozen soil is formed around the freezing pipe by circulating a refrigerant in the freezing pipe, forcibly causing a flow in a predetermined direction with respect to groundwater. By controlling the propagation direction of the cooling heat diffused from the freezing pipe, the freezing control method in the freezing method. 2. The freezing control method in the freezing method according to claim 1, wherein the flow velocity of the flow generated in the groundwater is maintained below the freezing limit flow velocity. 3. A first control step of controlling the flow velocity of the flow generated in the groundwater to be equal to or higher than a freezing limit flow velocity and expanding an unfrozen low temperature region in a predetermined direction, and stopping the flow of the groundwater or reducing the flow velocity. The freezing control method in the freezing method according to claim 1, further comprising a second control step of freezing the unfrozen low temperature region. 4. When forming a continuous frozen soil wall around frozen pipes arranged at intervals, the frozen pipes are arranged in a row until the frozen soil generated for each frozen pipe is merged. In addition to causing the flow of groundwater in the direction,
The frozen control method according to claim 2 or claim 3 is used to form an eccentric section of frozen soil around each freezing tube, and after the frozen soil generated for each freezing tube is combined,
A method for controlling freezing in a freezing method, which comprises growing frozen soil while stopping the flow of groundwater. 5. The freezing method according to claim 1, wherein the flow of groundwater is caused by pumping groundwater or pouring water into groundwater, and controlling the flow rate of groundwater by controlling the groundwater pumping amount or pouring amount. Freezing control method.