JP5462097B2 - Ant-proof drug injection system - Google Patents

Description

  The present invention relates to a system for injecting an ant-preventing agent into soil in order to prevent white ant damage in a building.

In order to protect buildings, particularly wooden houses, from white ant damage, in many cases, ant-proofing treatment is performed by applying or spraying an ant-proofing agent to the foundation and the base of the building when the building is built. However, it is said that the effect of the ant-proofing agent lasts for 5 years, and it is necessary to repeat the ant-proofing treatment by applying or spraying this ant-proofing agent to the foundation and the base of the building every 5 years after construction. .
However, the foundation and the foundation part of the building are very narrow, and it is very difficult to apply or spray the ant-proofing agent without being left unpainted and even after construction. Moreover, it is difficult to completely eliminate white ants that inhabit the ground simply by applying or spraying the ant-proofing agent on the foundation and the surface of the foundation of the building.

  In order to cope with this problem, there has been proposed an ant protection equipment in which pipes provided with a large number of orifices for injecting ant protection chemicals into the soil are buried in the ground near the foundation of the building (for example, Patent Documents). 1).

JP-A-8-49316

  In the ant defense equipment described in Patent Document 1, pipes provided with a large number of orifices for injecting ant proofing chemicals into the soil are provided at least under the ground in the foundation work of the building. It is formed by placing soil concrete. In addition, this pipe is provided with an inlet for injecting the ant-proofing agent into the pipe from the outside, and by injecting the ant-proofing agent from this inlet, even after the completion of the building, When piping is also performed under the floor or in the ground around the building, the termite-proofing agent can be injected relatively easily into the ground around the building.

  However, with this equipment, since a pipeline for soil injection is buried under the floor of the building, a large-scale construction is required, which may increase the installation cost. In addition, after placing soil concrete at the time of new construction, it is not possible to change pipes or change the piping route of pipes, resulting in maintenance problems and inability to deal with malfunctions. Problems arise.

In addition, for example, even if the pipe buried under the floor of the building is not properly routed or the pipe is leaked from the pipe for some reason, Since such a malfunction cannot be checked from the entrance, there may be a problem of reliability related to the spraying of the termite-preventing agent. Moreover, since the ant-proofing agent is also injected into the soil under the floor, there is a risk that a resident may have a health problem inhaling the ant-proofing agent in the air.
Furthermore, since a complicated piping route that requires many branches from one injection port is required, there is a possibility that the anti-anticide is not sufficiently sprayed at a location away from the injection port.

  Therefore, the object of the present invention is to solve the above-mentioned problems, realize a low cost by not requiring a large-scale construction, and can respond to a request for maintenance and repair even after construction. An object of the present invention is to provide a system for injecting ant-preventing chemicals that sufficiently considers health problems and exhibits a sufficient ant-repellent effect. A further object of the object of the present invention is to provide a system for injecting ant repellents which can check whether or not a pipe for injecting ant repellents into soil is defective.

  In order to solve the above-mentioned problem, one embodiment of the ant-proofing agent injection system of the present invention is an injection port that is embedded so as to surround the foundation along the outer periphery of the foundation of the building, and that both ends thereof are accessible from the ground. One or more pipelines, and injecting the propellant with a propellant from at least one of the inlets at both ends, and injecting the propellant with the propellant into the soil from a plurality of holes provided in the pipeline It is characterized by doing.

  Here, the “propagating ant-preventing agent” is an ant-preventing agent that uses a white ant's behavior such as grooming to propagate the agent from the white ant to the white ant to eliminate more white ants. Of the two species of white ants that mainly live in Japan that are subject to control, it is said that there is a range of action of 100 m or more for termites and about 10 m for termites. In addition, white ants form complex ant tracts that are branched in three dimensions in three dimensions due to the effects of soil humidity and hardness, presence of food, obstacles, and repellents in the soil. Therefore, by uniformly injecting the ant-preventing chemical around the building, at least a part of the white ant trying to enter the building can surely come into contact with the chemical. ) It can be expected that the drug is propagated to the whole, and this can be expected to kill all white ants. Note that the “Bait Method” defined by the Japan Shirori Countermeasures Association as “Maintenance-type Baitoe method” in the “Practical Control Construction Standard Specification” also uses a technique for propagating drugs. In this bait method, the drug is usually placed in a dot shape in a container installed at a distance of 1 to 5 m along the outer periphery of the foundation and about 10 to 30 cm deep from the ground surface. Is injected into the soil in a linear manner, so that the white ants can be more easily brought into contact with the drug.

  In addition, “injecting the propagating ant-proofing agent from at least one of the injection ports at both ends” includes the case of injection from one of the injection ports and the case of injection from the injection ports at both ends. More specifically, for example, as shown below, there is a case where a propagating ant-preventing agent is injected from one injection port and then a propagating ant-preventing agent is injected from the other injection port. The case where a propagating ant proofing agent is simultaneously injected from the injection port is also included.

According to this embodiment, a sufficient amount of the ant-proofing agent can be uniformly injected throughout the pipeline by injecting the ant-proofing agent from at least one of the inlets at both ends of the pipeline. In addition, by using a propagating ant-proofing agent as the ant-proofing agent, piping is not performed inside the foundation of the building but a pipeline is embedded only outside the foundation, thereby obtaining a sufficient ant-proofing effect. be able to.
This eliminates the need to embed a pipeline under the floor, avoiding large-scale construction and reducing installation costs. In addition, since the construction is performed only outside the foundation of the building, it is possible to respond to maintenance and repair requests even after construction, and it is possible to newly install this ant-preventing chemical injection system after construction of the building. Furthermore, since the ant-proofing agent is not sprayed under the building floor, it is excellent in terms of the health of residents.

  In another embodiment of the ant-proofing agent injection system of the present invention, a predetermined amount of the propagating ant-proofing agent is injected from one of the inlets at both ends, and then the one inlet is closed. In the state where the injected chemical solution remains in the pipeline, the propagating ant-preventing agent is injected into the soil by injecting the propagating ant-preventing agent from the other of the two inlets. It is characterized by injecting.

  According to this embodiment, by injecting a predetermined amount of the ant protection chemical from one inlet, a part of the ant protection chemical is injected into the soil from the plurality of holes, and the remaining ant protection chemical flows in the pipeline. As a result, the other injection port is reached and the pipeline is filled with the ant-proofing agent. Thereafter, one injection port into which the ant-proofing agent has been injected is closed, and the ant-proofing agent is injected into the pipeline from the other injection port. At this time, until the start of injecting the ant repellent agent from the other injection port, a part of the filled ant repellent agent flows out from the plurality of holes to the soil, but the ant repellent agent solution remains sufficiently in the pipeline. In this state, one of the injection ports (that is, the endmost portion in the injection in the opposite direction) is closed, and the ant-preventing drug can be injected from the opposite direction. Therefore, it is possible to inject a sufficient amount of the termite-preventing agent throughout the pipeline. In particular, when the pipeline is long, there is a risk that the amount of the ant-repellent agent injected into the soil from the hole provided in the area away from the inlet may be insufficient, but the ant-repellent agent may be injected from the opposite inlet. When injecting, such a region is located near the inlet, so that a sufficient amount of ant-protecting agent can be injected into the soil, and a sufficient amount of agent can be injected evenly over the entire area of the pipeline. it can.

  Another embodiment of the ant-proofing agent injection system of the present invention further comprises two or more pipelines having no branch points, and one inlet of the pipeline and one inlet of the other pipeline. It is characterized in that they are arranged adjacent to each other. Here, if there are two pipelines, the inlets at both ends of one pipeline are usually arranged on opposite sides of the surrounding foundation, and one inlet and the other note of the two pipelines are arranged. Entrances are arranged adjacent to each other.

  According to this embodiment, since the pipeline does not have a branch point and the soil injection of the ant-proofing agent is performed using the two pipelines, the soil injection of the ant-proofing agent can be stably performed throughout the pipeline. realizable.

  Another embodiment of the ant-proofing agent injection system of the present invention is further characterized by including one pipeline having no branch point, and the inlets at both ends being arranged adjacent to each other.

  According to the present embodiment, since the pipeline does not have a branch point, it is possible to stably realize the soil injection of the ant-repellent agent evenly throughout the pipeline. Moreover, since the two connection points are arranged adjacent to each other, it is excellent in convenience in operations such as injection and inspection of ant-proofing agents.

  The other embodiment of the ant-proofing agent injection system of the present invention further includes one pipeline having two branch points respectively communicating with the inlets at both ends, and the pipeline includes the two locations. Two pipeline regions having both ends of a branch point are provided, and the two pipeline regions are embedded so as to surround the foundation along the outer periphery of the foundation, and the flow resistance in the two pipeline regions is approximated. As described above, the two branch points are arranged.

  According to this embodiment, the termite-proofing agent injected from the injection port is divided into left and right at the branch point and flows through the two pipeline regions. In this case, in this embodiment, the two branch points are arranged so that the flow resistances of the two pipeline regions are approximated, so that the injected ant-preventive drug is almost evenly distributed in the two regions of the pipeline. Flowing. Therefore, in the present embodiment, the soil injection of the ant-repellent agent can be realized evenly throughout the pipeline with a simple structure using the branch.

  In another embodiment of the ant-proofing agent injection system of the present invention, a liquid is injected from one of the injection ports at both ends, and the injected liquid is the other injection port of the injection ports at both ends. The presence or absence of liquid leakage in the pipeline is confirmed by confirming the amount of the liquid that reaches the water.

  According to the present embodiment, for example, when damage is caused in the pipeline for some reason and the injected antifungal agent is leaking, the amount of the injected liquid reaching the other injection port is confirmed. As a result, liquid leakage can be detected appropriately, and highly reliable ant-preventive drug injection can be realized. Note that “checking the amount reaching the inlet” includes determining whether or not the injected liquid has reached the inlet.

  Another embodiment of the ant-proofing agent injection system of the present invention is characterized in that the pipeline is covered with a pipe cover made of a material having liquid permeability or liquid permeability.

  According to this embodiment, the termite-proofing agent that has flowed out of the hole opened in the pipeline is once stored in the pipe cover, and gradually and evenly from the pipe cover made of a material having liquid permeability or liquid permeability. Injected into the soil. Thereby, it can be expected that the ant-proofing agent is injected almost uniformly into the soil around the pipeline.

  Another embodiment of the ant-proofing agent injection system of the present invention is characterized in that the plurality of holes are opened in a direction above the circular horizontal line in the circular cross section of the pipeline.

Although the ant-proofing agent that has flowed out of the pipeline flows downward due to gravity, according to the present embodiment, the ant-proofing agent flows out from the hole formed in the upper direction from the circular horizontal line. The soil injection of the ant-preventive drug can be expected around the area. In addition, as described above, after injecting an ant-proofing agent from one inlet, and then injecting an ant-proofing agent from the inlet on the opposite side, injecting the ant-proofing agent with more ant-protecting agent remaining However, when a hole is formed in a direction above the circular horizontal line, the amount of the ant-preventing agent leaking out through the hole can be suppressed. Moreover, about the ant preventive medicine which accumulates in a pipeline after predetermined amount injection | pouring, it can prevent that an ant preventive medicine is wasted by inject | pouring clear water and pushing out a residual liquid at the last process.
In addition, from the viewpoint of uniform soil injection of the ant-proofing agent, it is advantageous that the number of holes to be evenly formed is larger, but there is also a problem that the manufacturing cost increases. For this reason, if these are judged comprehensively, it can be said that it is preferable to make a hole in 1-4 directions above a horizontal line.

  Another embodiment of the ant-proofing agent injection system of the present invention is characterized in that the plurality of holes are formed at a pitch of 10 to 30 cm in the longitudinal direction of the pipeline.

  According to this embodiment, since the holes are formed at a pitch of 10 to 30 cm in the longitudinal direction of the pipeline, it is possible to effectively implement soil injection of the ant-proofing agent over the entire area of the annular pipeline.

As described above, in the ant-proofing agent injection system of the present invention, a sufficient amount of ant-proofing agent is uniformly distributed throughout the pipeline by injecting the ant-proofing agent from at least one of the inlets at both ends of the pipeline. By injecting a propagating ant-proofing agent as an ant-proofing agent, a sufficient ant-proofing effect can be obtained only by burying a pipeline only outside the foundation. This eliminates the need to embed a pipeline under the floor, avoiding large-scale construction and reducing installation costs. In addition, since the construction is performed only outside the foundation of the building, it is possible to respond to maintenance and repair requests even after construction, and it is possible to newly install this ant-preventing chemical injection system after construction of the building. Moreover, since the ant-proofing agent is not sprayed under the building floor, it is excellent in terms of the health of the resident.
Furthermore, in the ant preventive drug injection system according to the present invention, the amount of the injected liquid that reaches the other injection port is confirmed to appropriately detect that the injected ant preventive liquid leaks in the system. Therefore, it is possible to realize highly reliable ant-preventive drug injection.

It is a top view which shows typically the whole structure of 1st Embodiment of the ant preventive medicine injection | pouring system of this invention. It is a top view which shows typically the whole structure of 2nd Embodiment of the ant preventive medicine injection | pouring system of this invention. It is a top view which shows typically the whole structure of 3rd Embodiment of the ant preventive medicine injection | pouring system of this invention. It is side surface sectional drawing seen from the arrow EE of FIGS. It is the side view seen from the arrow FF of FIGS. It is an enlarged view of the pipeline part shown in FIG. It is a graph which shows the measurement result of the chemical | medical agent quantity in the ground in the case where the ant-proofing agent is injected from one side and the case where the ant-proofing agent is injected from both sides. It is sectional drawing which shows typically other embodiment of the pipeline which concerns on this invention from which the diameter of the hole for soil injection | pouring an anti-anticide is different. It is sectional drawing which shows a pipeline typically, in order to compare the case where an ant-proofing agent is inject | poured from one side, and the case where an ant-proofing agent is simultaneously injected from both sides.

An embodiment of the ant-proofing agent injection system of the present invention will be described below in detail with reference to the drawings.
(Description of the first embodiment of the ant-proofing agent injection system of the present invention)
First, the configuration of the first embodiment of the ant-proofing agent injection system of the present invention will be described with reference to FIGS. 1 and 4 to 6. Here, FIG. 1 is a plan view schematically showing the overall configuration of the first embodiment of the ant-proofing agent injection system of the present invention, and FIG. 4 is a side cross-sectional view as seen from arrows EE in FIG. FIG. 5 is a side view seen from the arrow FF in FIG. 1, and FIG. 6 is an enlarged view of the pipeline shown in FIG.

  In FIG. 1, the ant-proofing agent injection system 2 of the present embodiment includes two pipelines 10 a and 10 b that have no branching points and are embedded so as to surround the foundation 30 along the outer periphery of the foundation 30 of the building. The inlets 20 accessible from the ground are formed at both ends of each pipeline 10a, 10b. In addition, the inlets 20 at both ends of each pipeline 10a, 10b are arranged on opposite sides of the foundation 30 (lower side and upper side in FIG. 1), and one of the two pipelines 10a, 10b (for example, FIG. 1). The lower injection port 20 is adjacent to each other, and the other injection port 20 (for example, the upper side in FIG. 1) is adjacent to each other.

Each pipeline 10a, 10b has a straight pipe 4 connected to each other via a 90 degree elbow 4a, is formed in a U-shape along the outer periphery of the foundation 30 of the building, and further has a 90 degree elbow 4a at both ends thereof. The connecting pipe 6 is connected via The connecting pipe 6 is bent upward at the end, and an injection port 20 is formed at the uppermost part thereof (see FIG. 5).
The pipe 4 constituting the pipelines 10a and 10b has a plurality of holes 14 for allowing the liquid to flow out of the pipe 4 (see FIGS. 4 and 6). The ant-proofing agent that flows through 4 flows out of the pipe 4 from the hole 14 and is injected into the surrounding soil in which the pipe 4 is embedded.
The pipe 4, the connecting pipe 6, the 90-degree elbow 4a, the branch member 8 to be described later, and the like can be made of a resin material such as hard vinyl chloride, but depending on temperature conditions, durability conditions, etc. Also, a metal material or the like can be used.

As shown in FIG. 4, the pipes 4 of the pipelines 10 a and 10 b are buried in the ground near the outside of the foundation 30 that supports the building 32. The distance between the pipe 4 and the outer surface of the foundation 30 is preferably about 0 to 50 cm, and more preferably about 0 to 20 cm. Moreover, the embedment depth of the pipe 4 is preferably about 5 to 50 cm, more preferably about 10 to 30 cm from the ground. The outer diameter of the pipe 4 is preferably about 1 to 10 cm, and more preferably about 1 to 3 cm. The diameter of the hole 14 is preferably 1 to 5 mm, and more preferably about 2 to 3 mm.
In the present embodiment, in the longitudinal direction of the annular pipeline 10, the holes 14 are preferably provided at a pitch of about 5 to 50 cm, and more preferably at a pitch of about 10 to 30 cm.

In the present embodiment, as in the enlarged view shown in FIG. 6, in the circular cross section of the pipe 4, the hole 14 is formed in the circular cross section of the pipe 4 in the direction above the circular horizontal line. In the embodiment shown in FIG. 6 (a), the holes 14 are formed in two directions, and in particular, are formed at substantially the same angle (for example, 60 degrees each) from the vertically upper side to both sides. In the embodiment shown in FIG. 6B, the holes 14 are formed in three directions, and the holes 14 can be formed in four or more directions. Since the liquid flowing out of the pipe 4 flows downward due to gravity, it is preferable to provide more holes 14 on the upper side of the circular horizontal line.
As will be described later, when the ant-proofing agent is injected from one injection port 20 and then injected from the other-side injection port 20, the more ant-proofing agent remains, from the opposite side. It is preferable to start the injection of the ant-proofing agent. At this time, when the hole 14 is provided above the circular horizontal line, it is possible to suppress the amount of the ant-proofing agent leaking outside through the hole 14.

Further, the outer side of the pipe 4 is covered with a pipe cover 12 in which fine holes (mesh) having liquid permeability are formed uniformly over the entire area. The pipe cover 12 of the present embodiment is made of polyethylene terephthalate nonwoven fabric, and is sewn on one side having a nonwoven fabric width of about 5 to 10 cm to form a cylindrical shape.
However, the pipe cover 12 is not limited to this, and any other material having liquid permeability can be used, and any material having liquid permeability can also be used. The size of the pipe cover 12 is preferably determined according to the outer diameter of the pipe 4 (for example, a gap of about 2 to 20 mm).

As a result, the termite-proofing agent that has flowed out of the pipe 4 from the holes 14 formed in two directions is once stored in the pipe cover 12 and injected into the soil from the evenly provided micropores (mesh). The soil can be injected almost uniformly around the pipe 4 at 360 degrees. Similarly, even between pitches in the longitudinal direction, soil injection can be performed almost evenly by storing the ant-proofing agent with the pipe cover 12. By combining the arrangement of the holes 14 formed in such two directions, the pitch size of the appropriate holes 14 and the pipe cover 12 provided with uniform micropores (mesh), the soil with uniform ant-proofing agent can be obtained. Injection can be realized.
Since the pipe cover 12 can prevent dirt and foreign matter from entering the hole 14 of the pipe 4 and can prevent the pipe 4 from being damaged, the soil injection of the ant-proofing agent can be realized stably for a long period of time.

  From the viewpoint of even soil injection of the ant-proofing agent, it is advantageous to make holes 14 in more directions and to make holes with a shorter pitch, but there is also a problem that the manufacturing cost increases. Therefore, considering the combination with the pipe cover 12 and the balance of the manufacturing cost, it can be said that it is preferable to open the holes 14 in the 1-4 directions on the upper side of the horizontal line of the circular cross section and to have a pitch of about 10 to 30 cm. .

  Further, as shown in FIG. 5, the four connecting pipes 6 extend into the pits 24 dug in the ground outside the foundation 30, and the inlet 20 formed at the end of the connecting pipe 6 Opening into the space in the pit 24. Thereby, the injection port 20 can be accessed from the ground. The inlet 20 is usually fitted with a cap 22 to prevent foreign matter from entering the connecting pipe 6 and the pipe 4. The pit 24 is also usually covered with a pit cover 26, and is usually considered so as not to be an obstacle around the building. The pit space in which the inlet 20 is provided can be realized by installing an inlet box that is integrally formed of resin and to which the pit cover 26 is also attached.

  Here, of the two pipelines 10a and 10b shown in FIG. 1, for example, in one pipeline 10a, both the inlets 20 formed in each of the two connection pipes 6 are opened, for example, 1 is connected to an injection port 20 (not shown) on the lower side of FIG. 1 to inject the ant-proofing agent, the ant-proofing agent flows through the connecting pipe 6 and is connected to the 90 ° elbow 4a (connection). It flows through the pipe 4 around the foundation 30 through point A). Part of the ant-proofing agent flows out of the pipe 4 from the hole 14 while flowing through the pipe 4, and the ant-proofing agent can be injected into the surrounding soil in which the pipe 4 is embedded.

The remaining ant-preventing chemical further flows through the pipe 4, reaches the inlet 20 on the upper side of FIG. 1 through the 90-degree elbow 4 a (connection point B) and the connecting pipe 6, and the ant-proofing agent enters the pipeline 10. Filled. After injecting a predetermined amount of the ant-preventing agent, the injection pump is removed from the lower injection port 20 in FIG. 1, the injection port 20 is closed, and the injection pump is connected to the upper injection port 20 in FIG. The injection of the ant-proofing agent into the pipeline 10 is started.
Until the injection of the ant-preventing chemical is started again, a part of the filled ant-proofing agent flows out from the plurality of holes 14 to the soil. As described above, the hole 14 is more than the horizontal line of the circular cross section of the pipe 4. If it is upward, the ant-preventing agent can be prevented from flowing out, and injection of the ant-preventing agent is started from the opposite direction with the injected ant-preventing agent remaining sufficiently in the pipeline. can do.

As described above, with the injected ant-preventing agent remaining sufficiently in the pipeline, the lower injection port 20 in FIG. 1 is closed and the ant-preventing agent is injected from the upper injection port 20 in FIG. Therefore, a sufficient amount of the ant-preventing agent can be injected into the soil from the hole 14. In particular, when the pipeline 10 is long, the ant is injected into the soil from the hole 14 provided in a region (for example, the region above the central region C in FIG. 1) away from the injection port 20 of the ant-protecting agent. Although there is a possibility that the amount of the medicine becomes insufficient, when the ant-proofing agent is injected from the inlet 20 on the opposite side, the region is located in the vicinity of the inlet 20, so that a sufficient amount of the ant-proofing is provided. Drug soil injection can be performed. Therefore, a sufficient amount of the termite-proofing agent can be evenly injected into the entire area of the pipeline 10a around the foundation 30.
In addition, soil injection of an ant-proofing agent can be performed in the same procedure for the other pipeline 10b.

  Moreover, in this embodiment, sufficient ant-proof effect can be acquired only by embedding the pipeline 10 in the outer side of the foundation 30 of a building by using a propagating ant-proofing agent. A technical explanation regarding this point will be described later.

  The soil injection of the ant-proofing agent can be carried out in order for one pipeline 10a, 10b, or two injection pumps are prepared and the ant-proofing agent is simultaneously injected into each pipeline 10a, 10b. You can also. In addition, although the time required for soil injection of the ant-proofing agent in one pipeline 10a, 10b varies depending on the soil, it is considered that about 30 seconds to 5 minutes is preferable. In the first embodiment, since there is no branch point in the flow path, it is possible to stably realize the soil injection of the ant-preventing agent evenly throughout the pipeline 10.

  In the present embodiment, since the foundation 30 has a substantially rectangular planar arrangement, each of the pipelines 10 and 10b has a U-shape, but is not limited thereto, and Even when it is embedded around a complex-shaped foundation or an asymmetrical foundation, it can have a shape along its outer periphery.

<Explanation regarding the injection procedure of ant-proofing agent>
Next, a procedure for injecting an ant-proofing agent using the ant-proofing agent injection system 2 configured as described above will be described.
The pipeline 10a will be described as an example. First, as shown in FIG. 4, two pit covers 26 are opened, the caps 22 attached to the two inlets 20 are removed, and the inlet 20 is opened. Let First, at one injection port 20, for example, the lower injection port 20 in FIG. 1, an injection pump (not shown) of an ant-proofing agent is connected to inject the ant-proofing agent into the pipeline 10a. The injected ant-proofing agent flows from the connecting pipe 6 through the pipe 4 around the foundation 30. And while flowing in the pipe 4, a part of the pipe 4 flows out from the hole 14 to the outside of the pipe 4, and the soil injection is performed, and the remaining ant-proofing agent flows over the central region C and passes through the connecting pipe 6. 1 overflows from the upper inlet 20 in FIG.

Here, it is possible to confirm the presence or absence of leakage in the pipeline 10a by confirming the amount of the ant-preventing agent overflowing from the upper injection port 20. For example, when damage is caused in the pipeline 10a for some reason and the injected antifungal agent is leaking, the amount reaching (overflowing) the other injection port 20 is reduced, or in some cases No reach at all. By confirming this, the liquid leakage can be detected properly, so that highly reliable ant-preventive drug injection can be realized.
In addition, if it is only confirmation of the presence or absence of a liquid leakage, it can also carry out by inject | pouring other liquids including water, and in this case, the possibility of wasting expensive ant-proofing agents can be avoided.

  Even in the case of flowing the liquid into the ant-preventing chemical injection system 2 for the first time, it is possible to grasp how much liquid reaches the other inlet 20 by the fluid simulation calculation. The presence or absence of leakage in the ant-proofing agent injection system 2 can be confirmed. In addition, once a check is made by actually flowing the liquid, it is possible to confirm the presence or absence of leakage from the next time on the basis of the flow rate measurement data.

When it is confirmed that there is no leakage by the above procedure, the soil injection of a predetermined amount of the termite-proofing agent is continued, and then the injection pump is removed from the lower inlet 20 in FIG. Install and close the opening. 1 is connected to the injection port 20 on the upper side of FIG. 1 to inject the ant-proofing agent into the pipeline 10a. Thereby, since the ant-proofing agent can be injected from the opposite side in a state where the ant-proofing agent remains sufficiently in the pipeline 10a, a sufficient amount of the ant-proofing agent can be injected into the entire area of the pipeline 10a. .
With respect to the other pipeline 10b as well, it is possible to properly detect the leakage by the same procedure, and subsequently, soil injection of the ant-proofing agent can be performed.

(Explanation of Second Embodiment of Anticide Injection System of the Present Invention)
Next, the structure of 2nd Embodiment of the ant-proofing chemical | medical agent injection | pouring system of this invention is demonstrated using FIG.2 and FIG.4-6. Here, FIG. 2 is a plan view schematically showing the overall configuration of the second embodiment of the ant-proofing agent injection system of the present invention. Similarly to the above, FIG. 4 shows the arrow EE in FIG. FIG. 5 is a side view seen from the arrow FF in FIG. 2, and FIG. 6 is an enlarged view of the pipeline portion shown in FIG.

  In the first embodiment shown in FIG. 1 which has already been described, the two pipelines 10a and 10b are provided, and the two pipelines 10a and 10b are divided in half and surround the foundation 30 of the building. The second embodiment shown in FIG. 2 is different in that one pipeline 10 is provided and the foundation 30 is surrounded by one pipeline 10. In the first embodiment, the inlets 20 at both ends of the pipelines 10a and 10b are arranged on opposite sides (up and down in FIG. 1) of the surrounding foundation 30, and one of the two pipelines 10a and 10b is placed. The injection ports 20 (for example, the lower side in FIG. 1) and the other injection ports 20 (for example, the upper side in FIG. 1) are arranged adjacent to each other. The difference is that the injection port 20 is disposed adjacently.

  For this reason, the ant-proofing agent injected from the left inlet 20 in FIG. 2 flows clockwise through the base 6 of the building through the connecting officer 6 and the 90-degree elbow (connection point A). The farthest central area C is reached and further advanced, through the other 90-degree elbow (connection point B) and connection 6 to the right inlet 20 in FIG. After the soil injection of a predetermined amount of the ant-proofing agent is performed in this manner, the left-side inlet 20 in FIG. 2 is closed, and this time, the ant-proofing agent is injected from the right-side inlet 20 in FIG. Perform soil injection. In this case, since the ant-proofing agent can be injected while the ant-proofing agent remains sufficiently in the pipeline 10, a sufficient amount of the ant-proofing agent can be injected into the soil. The other points are generally the same as those in the first embodiment, and further detailed description is omitted.

  Even in the second embodiment, since there is no branch in the flow path, a predetermined flow rate of the ant-repellent agent can be flowed in a stable state, and soil injection of the ant-repellent agent evenly throughout the pipeline 10 is stabilized. Can be realized. Further, since the two injection ports 20 are adjacent to each other, the handling of the drug injection pump and the leakage check of the pipeline using one of the injection ports can be performed with less effort.

(Description of the third embodiment of the ant-proofing agent injection system of the present invention)
Next, the structure of 3rd Embodiment of the ant preventive medicine injection | pouring system of this invention is demonstrated using FIGS. Here, FIG. 3 is a plan view schematically showing the overall configuration of the third embodiment of the ant-proofing agent injection system of the present invention, and FIG. 4 is a side cross-sectional view as seen from arrows EE in FIG. FIG. 5 is a side view seen from the arrow FF in FIG. 3, and FIG. 6 is an enlarged view of the pipeline portion shown in FIG.

In FIG. 3, the ant-proofing agent injection system 2 of the third embodiment includes one pipeline 10 having two branch points A and B, and the pipeline 10 has two branch points A and B at both ends. And two pipeline regions 10a (a pipe route connecting the points ACB) and a pipeline region 10b (a pipe route connecting the points ADB). Pipeline regions 10a and 10b form an annular pipe route surrounding the foundation 30 along the outer periphery of the foundation 30 of the building.
In the pipeline regions 10a and 10b, two connecting pipes 6 are connected via branching members (T-shaped connectors) 8 at branch points A and B. Each of the two connecting pipes 6 is connected to the pipeline regions 10a and 10b at one end (branching points A and B) (via the branching member 8), and the other end serves as an injection port 20 for the ant-proofing agent. .

  The pipeline regions 10a and 10b are formed in an annular shape as a whole so that the straight pipe 4 is connected to each other via the branch member 8 and the 90-degree elbow 4a and surrounds the outer periphery of the foundation 30. A plurality of holes 14 for allowing liquid to flow out of the pipe 4 are formed in the pipe 4 forming the annular pipe route (see FIGS. 4 and 6). The ant-proofing agent that flows through 4 flows out of the pipe 4 from the hole 14 and is injected into the surrounding soil in which the pipe 4 is embedded.

  Here, the injection pump (FIG. 3) of the ant-proofing agent is injected into one of the two inlets 20 formed in each of the two connecting pipes 6 (for example, the lower inlet 20 in FIG. 3). (Not shown) and the ant-proofing agent is injected, the ant-proofing agent flows in the connecting pipe 6 and at the branch point A (branching member 8), the ant-proofing agent is divided into left and right, That is, it flows in the pipeline region 10a and the pipeline region 10b. And while flowing in each pipeline area | region 10a and 10b, it can flow out of the pipe 4 from the hole 14, and can inject | pour an anti-anticide into the surrounding soil in which the pipe 4 was embed | buried. The remaining ant-preventing agent further flows in the pipeline regions 10a and 10b and reaches the inlet 20 on the upper side in FIG. 3 from the branch point B (branch member 8). In this way, after the soil injection of a predetermined amount of the ant-preventing agent is performed, the injection pump is then removed from the lower injection port 20 in FIG. 3, the injection port 20 is closed, and the upper injection port in FIG. An injection pump is connected to the injection port 20, and this time, the soil injection of the termite-proofing agent is started from the opposite side. In this case, since the ant-proofing agent can be injected while the ant-proofing agent remains sufficiently in the pipeline 10, a sufficient amount of the ant-proofing agent can be injected into the soil.

  Even in the present embodiment, by using the propagating ant-proofing agent, a sufficient ant-proofing effect can be obtained only by burying the pipeline 10 outside the foundation of the building. A technical explanation regarding this point will be described later.

  In the present embodiment, the two branch points A and B provided in the pipeline 10 are arranged at substantially opposite positions of the annular pipe route (the pipeline regions 10a and 10b). Thereby, the flow resistance of the pipeline area | region 10a and the flow resistance of the pipeline area | region 10b become substantially the same. In the present embodiment, since the foundation 30 has a substantially rectangular planar arrangement, the pipeline region 10a and the pipeline region 10b have a substantially symmetrical arrangement. However, the present invention is not limited to this. Even when the annular pipeline 10 is embedded around a foundation having a more complicated shape or a foundation having an asymmetric shape, the branch points A and B are both ends. In the two pipeline regions 10a and 10b, the branch points A and B can be positioned at positions where the flow resistances of the respective pipeline regions approximate.

  By making the flow resistances of the pipeline region 10a and the pipeline region 10b approximate, branching points A and B are divided into left and right from the connection pipe 6 and flow in the pipeline region 10a and the pipeline region 10b. The drug flow rate can be made substantially the same. Therefore, in the pipeline area | region 10a and the pipeline area | region 10b, the soil injection | pouring of a substantially equal ant-proofing agent is realizable.

  In the present embodiment, there is a branch point where the flow is divided into right and left in the flow path, but the pipelines are arranged by arranging the branch points A and B so that the flow resistances of the two pipeline regions 10 and 10b are approximated. By making the flow rate of the ant-preventing chemical flowing through the region 10a and the pipeline region 10b substantially the same, it is possible to realize soil injection of the same ant-preventing agent in both regions.

(Comparison test of drug distribution between one-sided injection and two-sided injection of ant-proofing drug)
Next, as described above, in order to verify the effect of injecting the ant-preventive drug from both sides of the pipeline, a comparative test of drug distribution between the one-side injection and the two-side injection was performed. In the tests described below, a pipe with a hole in which holes having a diameter of about 2 mm were formed at a pitch of 20 cm was used.

In the test of injecting an ant-proofing agent from one side, a pipe with a hole of about 24 m in length is embedded to a depth of about 20 cm, one end is closed, an injection port is formed at one end, and propagation A dilute solution of an anti-fungal agent was injected into the soil by injecting 120 L from an injection port on one side.
On the other hand, in the test in which the ant-proofing agent is injected from both sides, a pipe with a hole of about 20 m in length is buried at a depth of about 20 cm, and injection ports are formed at the left and right side ends, thereby propagating ant-proofing agent. After injecting 50 L of the diluted solution from one end and injecting the soil, this end is closed, and the diluted solution of the injected propagating ant repellent remains sufficiently in the pipe, and the opposite end The soil was injected by injecting 50 L of a dilute solution of a propagating ant control agent (total of 100 L).

  On the next day of the drug injection day, soil samples at points 0, 1, 4, 10, 16, 19, and 20 m were collected from the injection port (one injection port in the case of bilateral injection). At one point, soil samples were collected at four locations around the pipe (upper left side, upper left side, lower right side, upper right side of the pipe). And the density | concentration of the active ingredient in a soil sample was measured, and the average value of four measured values was made into the chemical | medical agent amount of each point.

Here, a test result is shown in FIG. The graph of Fig.7 (a) shows the chemical | medical agent amount in each point in single side injection | pouring, and the graph of FIG.7 (b) shows the chemical | medical agent amount in each point in bilateral injection | pouring. Here, the horizontal axis of the graph indicates the distance (m) from the injection port, and the vertical axis indicates the drug amount (ppm).
As shown in FIG. 7 (a), in the case of one-side injection, the amount of drug present in the soil decreases as the distance from the injection port decreases, and decreases to around 5 ppm at a point 10 m from the injection port. On the other hand, in both-side injection, as shown in FIG. 7 (b), even at the 10m point (central region) farthest from the injection ports on both ends, the drop in the amount of drug is relatively small, and the entire area where the pipe is embedded It was demonstrated that a sufficient drug amount of 10 ppm or more was injected.

(Description of other embodiment regarding hole 14)
Next, another embodiment related to the hole 14 will be described with reference to FIG. In the flow path of the pipeline 10, the kinetic energy of the flow of the ant-preventing chemical gradually decreases as the distance from the injection port 20 decreases, so that the amount of the ant-preventing chemical that flows out from the hole 14 decreases. Therefore, in order to cope with this, in the embodiment shown in FIG. 8, the diameter of the hole 14 is increased as the distance from the inlet 20 increases in the flow path of the pipeline 10. The diameters of the holes 14 arranged in order from the inlet 20 are d1, d2, d3, d4. Assuming d5 and d6, d1 <d2 <d3 <d4 <d5 <d6.
Thereby, even if it is little kinetic energy, more ant preventive medicine can be made to flow out of hole 14. The change in the size of the hole 14 is preferably determined optimally for each pipeline 10 in consideration of the length and shape of the pipeline 10.

(Description of embodiment in which ant-proofing agent is simultaneously injected from both ends)
In each of the above embodiments, the ant-proofing agent is injected from one end of the pipeline, and then the ant-proofing agent is injected from the opposite end of the pipeline. An embodiment in which the ant-proofing agent is injected at the same time is also conceivable. This embodiment will be described below.
FIG. 9 is a cross-sectional view schematically showing a pipe for injecting the ant-proofing agent into the soil. In FIG. 9A, an inlet is formed at one end, and in FIG. As in the present invention, the injection ports 20 are formed at both ends. The arrow indicates the flow of the ant-proofing agent, and the flow rate (flow rate) is indicated by the length of the arrow.

  FIG. 9A shows a case where an anti-anticide is injected from the injection port on one side. Each time the ant-proofing agent injected from the inlet passes through the hole formed in the flow path, a part of it flows out of the pipe from the hole, and the remaining ant-proofing drug flows in the flow path. . As this is repeated, the flow rate of the ant-preventing chemical flowing through the pipe decreases, and at the same time, the kinetic energy of the flow of the ant-preventing chemical decreases, so that it flows out of the hole as shown by the arrow in FIG. The flow rate of the ant-proofing agent gradually decreases. For this reason, in the central region farthest from the injection port, there is a possibility that a sufficient amount of the termite-proofing agent is not injected into the soil.

In FIG.9 (b), embodiment of the pipe 4 which comprises the pipeline 10 of this invention is shown typically. In this case, the ant-proofing agents are simultaneously injected from the injection ports 20 on both sides, and each ant-proofing agent flows in the left and right direction, and the flows collide in the vicinity of the central region. Therefore, the ant-proofing agent can obtain energy by the same effect as the so-called “water hammer”.
As in the case shown in FIG. 9 (a), a part of the ant-proofing agent injected from the injection port 20 passes through the hole 14 formed in the flow path, and a part of the ant-proofing agent is injected from the hole 14 to the outside of the pipe. Since the remaining ant-preventing agent flows through the flow path, the flow rate of the ant-preventing agent flowing out from the hole 14 gradually decreases and the kinetic energy also decreases as it leaves the inlet 20. On the other hand, as it approaches the center region, it receives energy due to the collision of the flow, so that it is possible to increase the flow rate of the ant-repellent agent flowing out from the hole 14.

  Accordingly, as shown by the arrow in FIG. 9B, the flow rate of the ant preventive drug flowing out from the hole 14 is less reduced than that in FIG. 9A, and the central region farthest from the inlet 20 However, a sufficient amount of anti-anticide can be injected into the soil.

  As described above, when the ant-proofing agent is injected from both ends at the same time, the ant-proofing agent flowing in the opposite direction collides with the central region, so that the same energy as that by the water hammer effect can be obtained. Even in the central region, this energy can be used to inject a sufficient amount of ant protection agent into the soil.

(Explanation on using propagating ant-preventing agents)
Next, explanation will be given on performing the ant-proofing treatment using the propagating ant-proofing agent. Here, the propagating ant drug is an ant drug that uses the behavior of white ants such as grooming to propagate the drug from the white ants to the white ants to eliminate more white ants.
As the insecticide used in the present invention, as shown below, a non-repellent and slow-acting drug that can be expected to have a propagation effect can be used.

Neonicotinod compounds: imidacloprid, clothianidin, nitenpyram, acetamiprid, thiamethoxam, thiacloprid, dinotefuran pyrrole compounds: chlorphenapyrphenylpyrazole compounds: acetoprole, ethiprole, fipronil, vaniliprole, pyriprole I, pyriprol 9
Insect growth regulators such as juvenile hormone-like substances and chitin synthesis inhibitors: pyriproxyfen, metoprene, hydroprene, phenoxycarb, diflubenzuron, teflubenzuron, flufenoxuron, bistrifluron, hexaflumuron, triflumuron, novallon, Chlorfluazuron, lufenunone, nobiflumuron buprofezin, exazole, cyromazine anthranilamides compounds: chlorantraniliprole oxadiazine compounds: indoxacarb nelistoxin compounds: cartap, bensultap, thiocyclam, monosultap Bisultap boron compounds: boric acid, borax and others: hydramethylnon, sulfuramide, etc.

  Examples of preparations include emulsions, emulsions, microemulsions, flowables, wettable powders, aqueous solvents, suspensions, etc., but depending on the drug, using formulation technology such as microencapsulation, In some cases, it is more effective to use a preparation with increased non-repellency and delayed action.

In addition, as an active ingredient of an insecticide, an organophosphorus compound, a pyrethroid-like pyrethroid-based compound, if it is not a non-repellent or slow-acting drug, but can be made into a preparation having a propagation effect by a preparation technique such as microencapsulation Insecticides such as compounds and carbamate compounds can also be used. When microencapsulated, the preparation becomes a suspension or the like.
Other insecticides are listed as follows.

  Organophosphorus compounds: propetanephos, acephate, aluminum phosphide, butathiophos, cadsafos, chloroethoxyphos, chlorfenvinphos, chlorpyrifos, chloropyrifosmethyl, cyanophos, diazinon, DCIP, diclofenthion, dichlorvos, dimethoate, dimethylbinphos, disulfoton, EPN, ethion, ethoprophos, etrimphos, fenthion, fenitrothion, phosthiazete, formothion, hydrogen phosphide, isofenphos, isoxathion, malathion, mesulfenphos, methidathion, monocrotophos, nared, oxydeprophos, parathion, hosalon, phosmet, pyrimiphosmethyl, pyridafenthione , Fentoate, Profenofos, Propafos, Pro Ojos, pyraclofos, salithion, sulprofos, tebupirimfos, temephos, tetra, terbufos, thiometon, trichlorfon, vamidothion, phoxim

  Pyrethroid-like, pyrethroid compounds: enfenprox, silafluophene, permethrin, acrinatrin, allethrin, benfluthrin, beta-cyfluthrin, bifenthrin, cycloprotorin, cyfluthrin, cyhalothrin, cypermethrin, dimefluthrin, deltamethrin, esfenvalerate, fenpropatrin , Fenvalerate, flucitrinate, flufenprox, flumethrin, fulvalinate, halfenprox, imiprothrin, metfurtothrin, praretrin, profluthrin, pyrethrin, resmethrin, sigma-cypermethrin, teflutrin, tralomethrin

  Carbamate compounds: fenobucarb, alaniccarb, bendiocarb, benfuracarb, carbaryl, carbofuran, carbosulfan, cloetocarb, etiofencarb, phenothiocarb, phenoxycarb, furthiocarb, isoprocarb, metorcarb, mesomil, methiocarb, NAC, oxamylporumil XMC, thiodicarb, xylylcarb

Dibenzoylhydrazine compounds: Chromafenozide, halofenozide, methoxyphenozide, tebufenozide Bacillus thuringiensis toxins: Bacillus thuringiensis viable spores and produced crystal toxins Tropolone compounds: hinokitiol, α-tupricin , Β-drabrin and note cutin alkylamine acetate: mixed or single alkylamine acetate having 8 to 18 carbon atoms phthalic acid diamide compounds: fulvendiamide macrolide compounds: abamectin, emamectin, milbemectin, milbemycin oxime, moxidectin, Spinosad triazine compounds: tripropyl isocyanurate naphthalene compounds: monochloronaphthalene chlorinated dialkyl ethers Additive compounds: octachlorodipropyl ether Others: pyridalyl etc.

  In the present invention, by using a propagating ant-preventing agent, it is not necessary to use a pipeline that has been buried under the floor in the past. Can be prevented. In other words, the chemical treatment layer of the propagating ant-repellent agent is only formed on the outside of the building foundation, which not only prevents the invasion of white ants on the outside of the building foundation, but also on the inside (under the floor) and ground of the building foundation. It is possible to prevent white ants that exist deep inside from reaching the foundation of the building and acting.

<Explanation of confirmation test of propagating ant-proofing agent for soil transfer>
Next, with the ant-proofing agent injection system of the present invention, after the propagation of the ant-proofing agent, the ant-proofing agent having a sufficient concentration for the ant-proofing effect remains even after a predetermined period of time has passed. A test was conducted to confirm whether or not

In this test, soil injection was performed using the same pipe and propagating ant-preventive drug as in the comparative test of drug distribution in single-sided and double-sided injection. Then, after 140 days, a sample of soil around the pipe at a distance of about 4.5 m from the injection port was collected, and the concentration of the propagating ant repellent contained in the sample was measured.
As a concrete test method, a soil injection of a propagating ant-preventing agent was performed at the end of June, and two samples (total of 11 samples from each of the 11 locations shown below were observed in mid-November after 140 days after the rainy season and typhoon season. 22 samples) were collected and tested.

  Stones and dust from each soil sample were removed in advance and dried overnight in a dryer (40 ° C.). After collecting the dried soil 25 in an Erlenmeyer flask, about 100 ml of methanol was added and extracted with an ultrasonic cleaner for 30 minutes. After ultrasonic extraction, the sample is immersed and extracted for about 2 hours with shaking, filtered, and the filtrate is distilled to dryness using a rotary evaporator. 1 ml of internal standard solution and 4 ml of acetone are dissolved in the dried product, and the filtrate is filtered. A test solution was obtained. The test results are shown in the following table (Table 1).

  As shown in Table 1, it was found that a sufficient amount of the propagating ant repellent remained within 10 cm around the pipe 4. From this test result, since the propagating ant preventive agent with a concentration of 1 ppm or more remains outside the foundation of the building, even after 140 days have passed since the rainy season and the typhoon time, it is practically sufficient It has been demonstrated that

<Explanation about the effect in the case of using a propagating ant preventive agent>
As described above, in the ant-proofing agent injection system according to the present invention, by using the propagating ant-proofing agent, it is possible to provide a practically sufficient ant-proofing effect by burying an annular pipeline only outside the foundation of the building. It can be demonstrated. This eliminates the need to embed an annular pipeline under the floor, avoiding large-scale construction and reducing installation costs. In addition, since construction is performed only on the outside of the foundation of the building, it is possible to respond to requests for maintenance and restoration even after construction, and a new anti-anticide injection system can be provided after construction of the building.

(Explanation regarding safety of ant-proof drug injection system)
In the ant-proofing agent injection system according to the present invention, by using the propagating ant-proofing agent, a practically sufficient ant-proofing effect can be exhibited by burying the pipeline only outside the foundation of the building. As a result, the anti-anticide is not sprayed under the floor of the building as in the prior art, so it can be said that the system is safer with respect to the health of residents. In order to confirm this point, using the ant preventive drug injection system of the present invention, the air concentration of the propagating ant preventive drug in the house when the propellant ant preventive drug is injected into the outside of the foundation of the house is determined. A test to measure was performed.

<Explanation of airborne concentration measurement test of ant-proofing agent>
In this test, 0.03% of an aqueous solution of a propagating ant repellent was injected from the inlet at 5 L / m, and the soil was injected outside the foundation of the house. During the treatment, 3 hours after the treatment, 24 after the treatment. After the time, the following three air concentrations were measured. The measurement results are shown in the following table (Table 2).

  As shown in Table 2, the amount of ant-preventive components in the air was less than the detection limit at any time during the treatment, 3 hours after the treatment, and 24 hours after the treatment. Thereby, since the ant preventive medicine injection system of the present invention is not sprayed under the floor of the building, the occupant is less likely to suck the ant preventive medicine, and is an excellent system in terms of the resident's health. It was proved.

(Description of other embodiments of the ant-proofing agent injection system of the present invention)
The ant-proofing agent injection system of the present invention is not limited to the above embodiment, and other various embodiments are included in the present invention.

2 Ant-preventive chemical injection system 4 Pipe with hole 4a 90 degree elbow 6 Connection pipe 8 Branching member 10 Annular pipeline 10a, b Pipeline area 12 Pipe cover 14 Hole 20 Inlet 22 Cap 24 Pit 26 Pit cover 30 Building foundation 32 Building

Claims (8)

One or more pipelines are embedded along the outer periphery of the foundation of the building so as to surround the foundation, and have inlets accessible from the ground at both ends thereof.
Injecting a propellant agent from at least one of the inlets at both ends, and injecting the propellant agent into the soil from a plurality of holes provided in the pipeline ,
After injecting a predetermined amount of the prophylaxis agent from one of the inlets at both ends, the one inlet is closed and the injected chemical remains in the pipeline. An ant-proofing agent injection system , wherein the propagating ant-proofing agent is injected from the other of the two inlets, and the propagating ant-proofing agent is injected into the soil . One or more pipelines are embedded along the outer periphery of the foundation of the building so as to surround the foundation, and have inlets accessible from the ground at both ends thereof.
Injecting a propellant agent from at least one of the inlets at both ends, and injecting the propellant agent into the soil from a plurality of holes provided in the pipeline,
The pipeline, anti ants drug infusion system that is characterized in that is covered with a pipe cover made of a material having a liquid-permeable or liquid-permeable.   2. The apparatus according to claim 1, further comprising two or more pipelines having no branch points, wherein one inlet of the pipeline and one inlet of the other pipeline are arranged adjacent to each other. The ant-proofing agent injection system according to 2. Comprising one said pipeline with no branching points,
3. The ant preventive drug injection system according to claim 1 or 2, wherein the injection ports at both ends are arranged adjacent to each other. It has one pipeline having an inlet accessible from the ground at both ends thereof, and two pipeline regions having two branch points respectively communicating with the inlets at both ends,
The two pipeline regions are embedded so as to surround the foundation along the outer periphery of the foundation, and are provided in the pipeline region by injecting a propellant agent from at least one of the inlets at both ends. An ant-proofing agent injection system for injecting the propagating ant-proofing agent into the soil from a plurality of holes,
The two so the flow resistance is approximated in the pipeline region, the two anti-ant drug infusion system that is characterized in that the branch point is placed. By injecting liquid from one of the inlets at both ends, and confirming the amount of the injected liquid reaching the other inlet of the inlets at both ends, the pipeline or the 6. The ant preventive drug injection system according to claim 1, wherein the presence or absence of liquid leakage in the pipeline region is confirmed. The said several hole is opened in the direction above a circular horizontal line in the circular cross section of the said pipeline or the said pipeline area | region , The any one of Claim 1 to 6 characterized by the above-mentioned. Ant-proof drug injection system. The ant-proofing agent according to any one of claims 1 to 7 , wherein the plurality of holes are formed at a pitch of 10 to 30 cm in a longitudinal direction of the pipeline or the pipeline region. Injection system.