JP5145180B2 - Ground hardening material injection method and its equipment - Google Patents

Description

  The present invention is a ground hardening material injection method and apparatus for creating a ground hardening material layer in the ground by high-pressure injection of ground hardening material into the target ground for the purpose of strengthening support of the building foundation ground or stabilizing the ground and stopping water. It is about.

  Conventionally, ground hardener injection for ground lining support, reinforcement support, or hardener layer construction for the purpose of water stoppage has been achieved by extending the reach of the hardener jet even a little to increase the diameter of the hardener layer. Various methods have been devised with ideal creation, and one of them is a method of extending the reach distance by encapsulating and protecting the hardener jet with air using a polymerization injection nozzle consisting of a core nozzle and an annular nozzle surrounding it. (See, for example, Patent Document 1).

  Furthermore, by making the inner wall of the side injection nozzle into a spiral structure, a means for extending the effective range by applying a spiral rotation to the hardened material jet jetted at a high pressure (see, for example, Patent Document 2) has been taken.

In addition, a swirling flow guiding structure is formed in a portion from the predetermined portion of the hardening material pumping flow path communicating with the core nozzle of the injection rod to the core nozzle to guide swirling of the pumping material to generate a swirling flow with less energy loss. (Japanese Patent Application No. 2007-128819) has been proposed by the present applicant.
Japanese Examined Patent Publication No. 7-100931 JP-A 63-289110

  However, since the injection nozzle that injects the ground hardening material at a high pressure is set on the side wall of the injection rod, the ground hardening material that has been pumped is refracted at a substantially right angle at the nozzle portion, and the turbulent flow generated at the bending portion. Therefore, there is a problem that the pumping energy is consumed and attenuated.

  Conventionally, the bottom of the core flow path for opening and closing the clear water injection hole at the tip of the injection rod has a ball valve seat formed in a concave shape below the branch of the flow path in order to ensure the closure of the injection hole due to the insertion of the ball. Therefore, the jet flow fed to the core flow path once descends to the concave portion of the ball valve seat and rises to the flow path branch, resulting in a great energy loss.

  Furthermore, if the injection pressure is increased in order to extend the reach of the hardener jet flow, there is a risk of it, and there is a risk of causing an unnatural load on the ground and causing phenomena such as ground uplift. However, such a large amount is necessary, and it becomes a heavy burden in terms of cost.

  The diameter of the hardened material pumping flow path in the conventional injection rod does not change greatly although there may be some difference in volume diameter due to structural reasons. Pumping energy due to the generation of turbulence due to bending etc. As for the consumption decay, as in the invention described in Patent Document 2, a helical rotation is applied to the hardening material jet to add energy at the time of injection, and the pumping force is consciously changed. Absent.

In order to solve the above-mentioned problems, the present invention provides a material pressure feeding core flow path for an injection rod in which a plurality of polymerization injection nozzles comprising a core nozzle and a surrounding nozzle are provided facing each other on the tip side wall. In addition, a swirl flow guiding structure is formed, and the pumping material from the core flow path is radially divided by abutment, and an arc shape formed by the inner wall of the core flow path and each inner wall of the plurality of branch flow paths are formed. In order to prevent the arc shape from forming a refracting portion at each opening, the arc of the opening cross section shown in FIG. The set position of the plurality of superposition injection nozzles that closes the flow channel end of the core flow path by a bulging curved surface and superimposes the arc of the opening cross section with the arc of the cross section of the core flow path opening to form an opening Multiple branch channels that divide the pumping material in response to , Which is constituted so as to face each nucleus nozzles of the plurality of polymerization injection nozzle.

  That is, a swirl flow guiding structure is formed in the material pumping core flow path to add energy to the hardening material jet, and the arc of the inner wall of the core flow path and the inner wall of the split flow path that divides the pumping material at the end of the core flow path By providing a plurality of branch passages that are formed by cross-sectionally polymerizing the arc to form the inlet, the ground hardened material that has been fed is prevented from being largely refracted in the nozzle portion.

  Cross-sectional polymerization of the inner wall arc of the core flow channel and the arc of the inner wall of the branch flow channel, and the cross-sectional polymerization of the inner wall arc of the branch flow channel and the inner wall arc of the core flow channel By removing the jet abutting protrusion of the peripheral arc wall corresponding to the jet swirl direction of the nozzle and forming the wall surface of the inlet into a streamlined curved surface shape along the jet swirl direction, the jet flow in a streamline shape along the swirl angle Was flown into the diversion channel, and the diversion to the nozzle part and the introduction to the injection nozzle port were made smooth.

  Also, conventionally, the jet flow pumped to the core flow path once descends to the concave portion of the ball valve seat and flows up to the flow path branch, corresponding to the great loss of energy. The terminal closed shape of the core flow path is formed into a bulging curved surface shape, and the jet flow is smoothly divided by curved surface abutting, so that the disappearance of the pumping energy conventionally generated by the terminal aggression is greatly suppressed.

  Next, the swirling jet formed by the swirling flow guiding structure of the core flow path is formed by cross-sectional polymerization of the arc of the inner wall of the core flow path and the arc of the inner wall of the branch flow path that divides the pumping material at the end of the core flow path. The flow inlets from which the jetting collision protrusions are removed split and extend into a plurality of branch channels with a spiral swivel angle, and each branch channel is provided with a swirl flow guiding structure that amplifies swirling energy and communicates with each core nozzle. The swirl propulsion force amplified is added to the high-pressure injection from the nuclear nozzle.

  Embodiments of the present invention will be described below with reference to the drawings. Reference numeral 1 denotes an injection rod. On the side wall of the monitor A attached to the tip portion, there are a core nozzle 21 at the center, and superposition jet nozzles 2 and 2 that surround and surround the circumference nozzle 22 and open. The core flow path 12 that is set and communicates with the spray material tank via the swivel 11 communicates with the core nozzle 21, and the air flow paths 13 and 13 communicate with the air supply unit communicate with the surrounding nozzle 22.

  In the core flow path 12, a swirl flow guiding structure 3 is formed helically on the inner wall surface of the flow path by a guide groove or ridge 31, and the flow path terminal is closed by a bulging curved surface shape 32, and a predetermined portion of the terminal portion In FIG. 4, a plurality of branch channels 4 and 4 are set, in which the arc 12a of the inner wall of the core channel and the arc 4a of the inner wall of the branch channel are cross-sectionally polymerized to form the inlet 41.

  The plurality of branch channels 4 and 4 divide the pumping material corresponding to the set positions of the plurality of polymerization injection nozzles 2 and 2 on the side wall of the tip, and are the same as those in the core channel formed in each predetermined part. A high-pressure jet flow to which the swirl propulsion force amplified by the swirl flow guiding structure 3b is respectively applied to the nuclear nozzle 21 via the swirl flow guiding structure 3b is injected from the nuclear nozzle 21 to the target ground. It is not always necessary to provide the swirling flow guiding structure 3b of the diversion channel.

  At the top of the bulging curved surface shape 32 that closes the end of the core channel 12, the inlet to the fresh water supply passage 15 that communicates with the fresh water ejection hole 14 that is set at the bottom of the tip of the rod 1 via the ball valve seat 33. Is set, and when the rod 1 is rotated and inserted into the target ground, drilling water for removing slime is supplied and ejected from the fresh water ejection hole 14 to the target ground.

  Note that the injection rod 1 may be inserted into the target ground not by turning the rod 1 itself, but may be turned using another device at the time of injecting the hardener, in which case a ball is used. Since the mechanism such as the fresh water ejection hole 14 and the ball valve seat 33 for closing the ejection hole 42 by the introduction of the valve 42 is not necessary, a simple and smooth streamlined bulging curved surface shape 32 is formed as shown in FIG. The collision division of the jet flow is performed smoothly, and energy consumption due to the collision division can be further suppressed. Further, the opening and closing of the fresh water ejection hole can be performed by a differential pressure valve, not by ball insertion. In this case, a differential pressure valve is set in place of the ball valve seat 33.

  The rear end of the injection rod 1 is a swivel 11, which is connected to the corresponding portion of each flow path in the rod and the hoses 8 and 8 connected to the injection material tank and is installed on the base 6 It is supported by the drive unit 5 and the operating mechanism 7.

  The rod 1 is configured as described above, and in the case of excavation insertion, a central flow path 12 that is switched to a fresh water supply path at the time of lowering excavation and a hardener supply path at the time of ascending injection of the hardener at the center thereof, and its outer periphery An air supply flow path 13 for supplying spray air to the surrounding nozzle 22 is formed in the part.

  The ground hardening material injecting device configured as described above is installed on the target ground. First, lubricating fresh water is supplied to the core flow path 12 and ejected from the tip ejection hole 14. The injection rod is inserted into the target ground G by the rotation of the excavating blade 9 of the rod crown and the injection rod 1.

  In this way, the injection rod 1 is propelled and inserted toward the target ground G, and when the predetermined depth is reached, the swivel 11 is removed and the ball 42 is inserted from the connecting portion communicating with the core flow path 12. The fresh water supply passage 15 is closed by being transferred to the ball valve seat 33 set at the top of the bulging curved surface shape 32 of the terminal.

  At the same time, the hose 8 that has been supplying fresh water until then is switched to a hardener. Cement-based hardener is used as the ground hardener, and air injection from the surrounding nozzle 22 is performed as a high-pressure jet with a hardener feed pressure of 20 to 40 megapascals and a hardener discharge amount of about 100 to 200 liters / minute. It is sprayed and the rising speed is set to about 6 to 20 minutes / meter depending on the soil quality and the formation diameter.

  In the core flow path 12, a swirl flow guide is spirally guided by guide grooves or ridges on the inner wall surface of the flow path leading to the distribution flow paths 4 and 4 that divide the pumping material through the bulging curved surface shape 32 of the flow path end. The high-pressure jet formed from the core flow path 12 to the abutting division with the bulging curved surface shape 32 is subjected to swirling energy by the swirling flow guiding structure 3 and collides with the bulging curved surface shape 32. The arc 12a on the inner wall of the core channel and the arc 4a on the inner wall of the branch channel 4 flow into the inlet 41 configured by cross-sectional polymerization.

  As shown in FIG. 3, the jet collision projecting portion 4b of the peripheral arc wall corresponding to the jet swirl direction of the inlet 41 is removed along the jet swirl direction, and the wall surface of the inlet is a streamlined curved surface along the jet swirl direction. Since it is configured in a shape, the jet flows into the flow channels 4 and 4 in a streamline along the swivel angle, and is further amplified by the swirl flow guiding structure 3b formed in each of the flow channels 4 and 4, and swirl propulsion is performed. The high-pressure jet flow to which the force is applied is swirled and injected from the nuclear nozzle 21 to the target ground G.

  The air supplied to the air supply path 13 is supplied to the surrounding nozzle 22 of the superposition jet nozzle 2 and is jetted as a composite jet fluid of the above-mentioned hardening material jet. The diameter of the core nozzle can be increased, and the hardener injection layer X having a long reach of the hardener jet can be formed in a shorter time.

  In the case of erection insertion, since the injection rod 1 is inserted into the erection hole prepared by another excavating means and connected to the hardener supply mechanism and the rod rotation mechanism, the drilling water for eliminating slime In addition to the need for the fresh water supply path 15, the injection hole 14, and the ball valve seat 33 and the ball 42 for supply of water and switching of the supply to the hardened material, the pressure feeding and injection process of the hardened material is the same as described above.

  In this way, a curing swirling jet of curing material and air is ejected from the polymerization jet nozzle 2 and the injection rod 1 is rotated or reciprocated by a predetermined angle while stepping up in the extraction direction and moving backward to rise. The material high-pressure jet Y drills and cuts the surrounding ground, crushes the soil particles, and forms a hardened material injection layer X in a cylindrical shape along the drive locus of the injection rod 1 on the target ground G.

  Next, an injection rod is set at an adjacent position, and a hardener injection layer is similarly formed to cross-join the flank portions to form a hardener injection layer. Further, the same hardener injection layers are successively formed. A predetermined injection layer structure is formed by adjoining each other in a predetermined shape.

Since the present invention is configured as described above, it prevents the pumping energy from being attenuated due to the generation of turbulent flow due to bending of the hardened material pumping flow path, and enhances the water wedge effect by enhancing the straightness of the perforated jet. The balance of the jet pressure reaction force applied to the rod is maintained by setting the nozzle to the backward position, and the addition of swirling energy by the swirling flow guiding structure 3 and the pressure feeding energy doubled by the flow path inner wall formed by the streamline curved surface It is possible to make use of it by efficiency.

The side of the longitudinal section of the injection rod tip which shows the example of the present invention and shows the main structure of the injection rod provided with the supply switching structure to supply the lubricating fresh water for the rod insertion by rotating excavation and the hardener Figure Similarly, a longitudinal sectional side view of the tip of the injection rod showing the structure of the main part of the injection rod for erection and insertion Similarly, the cross-sectional schematic diagram of the cross section of the core channel and the branch channel showing the structure of the branch channel inlet configured by cross-sectional polymerization of the arc of the inner wall of the core channel and the arc of the inner wall of the branch channel Similarly, an explanatory diagram of the construction of the injection device showing the construction status of the ground hardening material injection layer construction and the entire ground from the side Similarly, the nozzle setting part enlarged front view of the injection rod showing the appearance from the front of the polymerization injection nozzle

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Injection rod 11 Swivel mechanism 12 Core flow path 12a Arc of inner wall of core flow path 13 Air flow path connected to surrounding nozzle 14 Fresh water ejection hole 15 Fresh water supply path 2 Polymerization injection nozzle 21 Nuclear nozzle of polymerization injection nozzle 22 Polymerization injection Nozzle surrounding nozzle 3 Swirl flow guiding structure 3b Swirl flow guiding structure of shunt flow communicating with core nozzle 31 Guide groove or protrusion 32 of swirl flow guiding structure 32 Swelling curved surface shape of core flow path end 33 Ball valve seat 4 Core 4a from the flow path 4a arc of the inner wall of the flow path 41 inlet of the flow path 42 ball 5 injection rod drive 6 base 7 injection rod operating mechanism 8 hose connected to the injection material tank 9 rod crown excavation blade A injection Rod tip monitor G Target ground X Ground hardener injection layer Y Hardener high pressure jet

Claims (6)

A swirl flow guiding structure is formed in the material flow-feeding core flow path of the injection rod provided with a plurality of superposition jet nozzles composed of a core nozzle and a surrounding nozzle on the side wall of the tip portion facing each other,
The feed material from the core flow path is radially divided by the collision, and the arc shape formed by the inner wall of the core flow path and the arc shape formed by each inner wall of the plurality of split flow paths are refracted at each opening. The flow channel end of the core flow channel is closed by a bulging curved surface that is divided into the inlet formed so that the arc of the cross section of the opening overlaps and joins so as not to form As well as
A plurality of branch passage for dividing the pumping material in correspondence with the set position of the plurality of polymerization injection nozzle, the injection rod to face each nucleus nozzles of the plurality of polymerization injection nozzle, to a predetermined depth of the target ground Inserted and grounded hardener with high pressure from the core of the superposition jet nozzle, and air is injected from the surrounding part while rotating the injection rod to create a cylindrical hardener injection layer Hardener injection method Corresponding to the jet swirl direction of the inlet formed so that the arc of the cross section of the opening overlaps and joins so that the arc shape formed by the inner wall in the plurality of branch channels does not form a refracting part at each opening The ground hardening material injecting method according to claim 1, wherein an injection rod having a streamlined curved surface along the jet swirl direction is used by removing a jet collision projecting portion of the peripheral arc wall. An injection rod configured to form a swirl flow guiding structure corresponding to a swirling direction at the time of inflow in each of a plurality of branch channels that divide the pumping material corresponding to a set position of the superposition injection nozzle. Ground hardening material injection method according to claim 1 or claim 2 A swirl flow guiding structure is formed in the material flow-feeding core flow path of the injection rod provided with a plurality of superposition jet nozzles composed of a core nozzle and a surrounding nozzle on the side wall of the tip portion facing each other,
The pumping material from the core flow path is radially divided by the collision, and the arc shape formed by the inner wall of the core flow path and the arc shape formed by the inner walls of the plurality of split flow paths have a refracting portion at each opening. The flow path end of the core flow path is closed by a bulging curved surface that is divided and introduced into the inlet formed so that the arcs of the opening cross section overlap and join so as not to form. With
Said plurality of said plurality of branch passage which corresponds to divide the pumped material to the setting position of polymerization injection nozzles, the plurality of polymer injection be made to face each nucleus nozzle ground cured material injection, characterized in the nozzle apparatus Corresponding to the jet swirl direction of the inlet formed so that the arc of the cross section of the opening overlaps and joins so that the arc shape formed by the inner wall in the plurality of branch channels does not form a refracting part at each opening The ground hardening material injecting device according to claim 4, wherein the jetting collision protrusion of the peripheral circular arc wall is removed and the wall surface of the inlet is formed into a streamline curved surface shape along the jet swirling direction. Injection rod, a plurality of branch passage for dividing the pumping material in response to the setting position of polymerization injection nozzle, according to claim 4 or claim that is configured to form a swirling flow induced structure corresponding to the turning direction during inflow, respectively Item 5. Hardening material injecting device for ground

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