KR101516674B1 - Soil improvement device - Google Patents

Abstract

1. A soil improving device for removing a compressed air from a nozzle and having a nozzle provided with a branching device for compressed air at a pipe leading end connected to a compressed air supply device for excavating the soil into a hole shape, The diameter of the pipe is larger than the outer diameter of the pipe so that the area (the area calculated from the diameter of the nozzle maximum outer diameter - the area calculated from the outer diameter of the pipe) / the nozzle diameter is 5 or more, Wherein a nozzle positioned on the same straight line is used.

Description

{SOIL IMPROVEMENT DEVICE}

The present invention relates to a soil improvement apparatus. More particularly, the present invention relates to a soil remediation apparatus capable of improving air permeability and water permeability of soil in which trees such as trees and trees are planted.

The soil located in the root part of the trees such as the garden, the roadside trees and the like is worsened by the stepping on, the roots growing due to the growth of the trees, and the like. The deterioration of the air permeability and water permeability of the soil adversely affects the growth of trees because the supply of oxygen or water to the plant roots becomes insufficient.

In order to solve this situation, it is thought that the soil located in the root part of the tree is plowed and overturned. However, in the case of digging while piercing the soil using a sharp rigid instrument such as a scorpion, the instrument may contact the root of the plant and injure the root, and in the case of improving the soil of the aquatic tree, There is a high possibility that the buried soil such as gas, electric power, water supply and drainage pipes disposed in a part of the pipeline is damaged.

[0004] Currently, as disclosed in Patent Document 1, there has been proposed a pneumatic soil-treating apparatus, more specifically, a pneumatic soil-treating apparatus, specifically, a ground inserting tube having a spraying nozzle at its tip end and an end of the spraying nozzle being inserted into the ground, And an air supply device for supplying compressed air to the underground insertion tube, wherein the underground soil processing device is provided with a tapered ashed shape extending in the outward direction toward the outer side, By injecting compressed air at a high pressure from the injection nozzle and softening the soil around the pipe inserted into the ground after inserting the insertion tube, it does not injure the gap of the root of the tree, Soil treatment such as restoration work is being carried out.

By the soil improvement treatment using such an airborne soil treatment apparatus,

(1) By drilling a hole in a soil and bringing the soil of the part to the surface, the soil density per unit area is lowered,

(2) The soil improvement material can be filled in the hole pierced in the soil, whereby the effect of soil improvement can be sustained over a long period of time,

(3) The compressed air that is ejected makes contact with the soil, thereby increasing the clearance of the excavated soil surface to improve the water absorbency and air permeability,

(4) Since the compressed air that is in operation penetrates into the soil, it is difficult to supply oxygen to the roots in the soil

However, in the case of using the pneumatic soil-treating apparatus described in this document, compressed air of 7 to 8 atmospheres is continuously sent at all times, and the total amount of compressed air required finally increases, For example, it is necessary to use a large-sized compressor having a weight of about 1 ton. Therefore, it is not easy to carry out the transportation of the compressor. In addition, there is also a problem that the work is difficult to proceed because the discharge ability of the soil is high and the soil is projected to the worker seriously, and the whole body is soiled with the soil which is sprung up after the work.

Since such an airborne soil treatment apparatus is constant in the outer diameter of the nozzle and has an outer diameter of about 30 mm in diameter, it is possible to prevent the large and small roots from sticking to each other at a high density in the vicinity of the root portion, It is difficult to insert the nozzle. In addition, since the entire apparatus including the hose is large in weight and the amount of air to be ejected is as large as 3.5 to 4.0 m ³ / minute (3500 to 4000 l / min), in addition to the size of the nozzle outer diameter, There is also the possibility of injury. Injuries of coarse roots often start to decay from the area, and as a result, damage to the wood itself results in special care in soil improvement work.

Japanese Patent Application Laid-Open No. 2006-22547 Japanese Patent Application Laid-Open No. 62-138103

It is an object of the present invention to provide a soil improving apparatus which is suitably used for the maintenance of trees such as trees and trees, and which makes it possible to improve air permeability and water permeability of the soil.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a soil remedying mechanism which has a nozzle provided with a branching device for compressed air at a pipe leading end connected to a compressed air supply device and excavates compressed air from a branching device to drill the soil into a hole , The maximum outer diameter of the outer periphery of the nozzle is made to be larger than the outer diameter of the pipe so that the area of the circle calculated from the area of the circle calculated from the diameter of the nozzle and the outer diameter of the pipe and the area of the nozzle impeller is 5 or more, A soil improvement device using a nozzle positioned substantially on the same straight line as a pipe having a substantially straight shape is used. Here, the nozzle is preferably used in a detachable state.

In the soil improving mechanism according to the present invention, the maximum outer diameter of the outer peripheral portion is set so that the outer diameter of the pipe is larger than the outer diameter of the pipe (the area calculated from the area of the circle calculated with the maximum outer diameter of the nozzle as the diameter - , The puffing nozzle is placed in a substantially straight line with the substantially straight pipe oriented in the direction of excavation. Therefore, the maximum outer diameter of the nozzle between the nozzle inserted in the soil and the upper side of the pipe between the soil and the soil, It is easy to form voids along the difference in outer diameter. As a result, an exhaust passage of the compressed air ejected into the soil is ensured, and the efficiency of the soil improvement work is remarkably improved. Further, by making the nozzle end tapered, the soil improvement work can be advanced by avoiding plant roots or obstacles.

Further, in the case of using this soil improvement mechanism, since a high pressure of about 25 atm can be used in an instant, the total amount of compressed air to be used is consequently reduced, and compared with a conventional air- (Compressed air supply device) can be handled with a small size. Therefore, the present invention can be effectively used for the maintenance of the number of trees or trees. In addition, since the air discharge time is short enough, the soil is sprung less and the workability is improved. On the other hand, since the maximum diameter of the nozzle can also be used lower than that of a conventional soil improvement mechanism, the nozzle of the soil improvement mechanism can be inserted from the gap of the root portion protection plate made of metal and difficult to move, have.

In addition, since the roots around the root portion of the tree tend to be thicker and larger in number, and the roots tend to be thinner and smaller as the distance from the root portion increases, the nozzles located at the root portion of the pipe penetrating near the root portion become obstructed Since the coarse nozzles can not be intruded, they need to be thinner. On the other hand, there is a need for a thicker nozzle so that the more roots are away from the root portion, the larger the number of roots. However, by using detachable nozzles, , The size of the nozzle can be appropriately changed according to the density of the roots from the vicinity of the root portion of the tree to the periphery thereof, and the substrate to be prepared can be made compact.

As described above, by supplying the compressed air into the soil by using the soil improving device according to the present invention, the concentration of oxygen in the soil is increased in a state in which labor is remarkably reduced and workability is improved compared to the prior art, , The productivity can be improved to improve the quality, and root rot of the plants in the land with poor drainage can be prevented, and it can play a role of the heart.

1 is a graph showing the relationship between the maximum outer diameter of the outer peripheral portion according to the present invention and the outer diameter of the pipe (the area calculated from the area of the circle calculated by taking the maximum outer diameter of the nozzle as the diameter - the area calculated from the outer diameter of the pipe) 1 is a perspective view showing an embodiment of a nozzle of a soil improvement device having a Kinnon nozzle; FIG.
2 is a graph showing the relationship between the maximum outer diameter of the outer peripheral portion according to the present invention and the outer diameter of the pipe (the area calculated from the area of the circle calculated by taking the maximum outer diameter of the nozzle as the diameter - the area calculated from the outer diameter of the pipe) Fig. 5 is a perspective view showing another embodiment of the nozzle of the soil remedying mechanism having a kinematic nozzle.
Fig. 3 is a perspective view showing that the grooves are formed in the longitudinal direction in the embodiment shown in Fig. 2;
4 is a graph showing the relationship between the maximum outer diameter of the outer peripheral portion according to the present invention and the outer diameter of the pipe (the area calculated from the area of the circle calculated by taking the maximum outer diameter of the nozzle as the diameter - the area calculated from the outer diameter of the pipe) Fig. 7 is a perspective view showing another embodiment of the nozzle of the soil improvement mechanism having the Kinnon nozzle.
Fig. 5 is a perspective view showing an embodiment shown in Fig. 4 in which a circular ring is fitted. Fig.
Fig. 6 is a perspective view showing a tip portion of a soil improving mechanism having no nozzle; Fig.

The soil improving device according to the present invention is characterized in that the nozzle has a nozzle provided with a branching device for compressed air at the pipe leading end connected to the compressed air supply device and has a maximum outer diameter of the nozzle is larger than the outer diameter of the pipe The area of the calculated circle - the area calculated from the outer diameter of the pipe) / the nozzle nozzle mechanism area is 5 or more, and the nozzle is placed on a substantially straight line with a substantially straight pipe oriented in the digging direction .

In the present invention, the nozzle refers to a hollow tube-like mechanical part used for determining a direction in which a fluid such as a gas or liquid flows. In general, nozzles are widely used to control the properties of fluids such as the flow rate, flow rate, direction, and pressure of the flowing material.

The maximum diameter of the outer periphery of the nozzle is set to be larger than the outer diameter of the pipe (the area calculated from the area of the circle calculated by taking the maximum diameter of the nozzle as the diameter - the area calculated from the outer diameter of the pipe) Is used. The mining mechanism can be provided on either the tip side or the side surface of the nozzle, but when the soil is excavated, it is preferably provided on the tip side of the nozzle. Here, the branch mechanism refers to a hole portion through which the compressed air is forcibly discharged, and has a smallest opening area. By using such a nozzle and locating the nozzle approximately on the same line as the substantially straight pipe oriented in the direction of excavation of the soil, the maximum outer diameter of the nozzle between the nozzle inserted in the soil and the upper side of the pipe, It is easy to form pores in accordance with the difference in outer diameter, so that an exhaust passage of the compressed air ejected into the soil is secured, and furthermore, the efficiency of the soil improvement work is remarkably improved.

Therefore, when no such nozzle is used, or when the maximum outer diameter of the outer peripheral portion is equal to the outer diameter of the pipe, voids are not formed between the side of the pipe inserted into the soil and the soil, It is difficult to secure an exhaust passage from the surface of the air to the ground, and the exhaust efficiency of the soil is reduced. Here, the bulging ratio (the area of the circle calculated with the maximum diameter of the nozzle as the diameter - the area calculated from the pipe outer diameter) / the area of the nozzle branching mechanism is 5 or more, and preferably 10 or more. Here, the area of the circle calculated from the diameter of the nozzle maximum outer diameter - the area calculated from the outer diameter of the pipe represents the cross sectional area of the soil which can be excavated by bulging the nozzle, and the area calculated from the pipe outer diameter is the pipe sectional area including the hollow portion , For example, in the case of a cylindrical pipe, the area of the circle having the diameter of the pipe becomes the diameter. In addition, the area of the circle calculated with the maximum outer diameter of the nozzle as the diameter is different from the nozzle cross-sectional area at the maximum outer diameter portion, for example, in the nozzle shown in Figs.

In Patent Document 2, compressed air is supplied from a feed air source to an air distributing body provided with a nozzle portion having a sharp-pointed tip with a tip end side in the form of an arrowhead, and compressed air Fig. 1 shows a nozzle section in which the maximum outer diameter of the outer periphery of the air intake tube or the air distribution body is larger than that of the air inlet. However, since the nozzle portion is not located on a substantially straight line with the substantially straight pipe extending to the ground facing the digging direction of the soil as in the present invention, There is no technical idea that voids are formed depending on the difference between the maximum outer diameter of the nozzle and the outer diameter of the pipe. Therefore, the excellent effect of the present invention, in which the exhaust passage of the compressed air ejected into the soil is ensured, and the efficiency of the soil improvement work is remarkably improved, can not be achieved at all.

It is preferable that at least one end portion of the nozzle has a tapered shape, and more preferably, the nozzle end portion connected to the pipe has a tapered shape. By making the end of the nozzle have a tapered shape, the soil improvement work can be carried out by avoiding plant roots or obstacles. Therefore, the angle of the tapered portion of the nozzle end connected to the pipe is preferably sharpened, and particularly preferably not more than 60 degrees. When the both ends have a tapered shape, that is, the angle of the partial conical surface constituted by the side surfaces of the tapered portion is preferably 120 占 or less, and preferably 90 占 or less. As a result, the roots divided by the nozzle tip end portion and the nozzle bulge portion are returned to their original positions after passing through them, so that it is easy to alleviate a situation in which the nozzle is broken when the nozzle is pulled out. On the other hand, if the angle of the tapered portion of the nozzle tip portion is excessively sharp, the excavating force is lowered.

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described with reference to the drawings.

Fig. 1 is a perspective view of a basic embodiment of the present invention. In Fig. 1, a branch pipe 2 for compressed air is provided at the tip of a pipe 1 connected to a compressed air supply device (not shown) The expansion nozzle 3 is provided so that the area of the circle / area calculated from the outer diameter of the pipe / the area of the nozzle / nozzle mechanism is 5 or more than the outer diameter of the nozzle. In this embodiment, the nozzle mechanism is located at the nozzle tip end, but when the nozzle minimum inner diameter exists inside the nozzle, the nozzle tip mechanism is a portion showing the minimum inner diameter in the nozzle tip direction. The bulging portion formed to be larger than the pipe outer diameter may be solid or hollow, and this is not limited to this embodiment. In this embodiment, the nozzle cross section may be a circular, elliptical or polygonal columnar body or a cylindrical body, preferably a columnar body having a triangular or larger shape is used. As such a columnar body, a commercially available nut may be fitted to the outer peripheral portion of the pipe front end.

In the embodiment shown in Fig. 2, both ends of the nozzle have a tapered shape showing an acute angle. That is, the bulge portion has a mountain-like shape in the longitudinal direction in which the diameter gradually decreases sequentially from the tip end portion of the nozzle 3, and then the diameter gradually decreases.

In the embodiment shown in Fig. 3, one or more sets of grooves 4 are formed in the longitudinal direction of the bulged portion of the mountain-like shape shown in Fig. 2. By forming such grooves, the resistance at the time of inserting the nozzle into the soil can be further reduced.

4, the columnar bodies 5, 5 ', 5' 'and 5' '' are formed as bulges at the nozzle tip, and the tip of the columnar body is connected to the nozzle branching mechanism 2 ). According to this aspect, it is possible to raise the excavating force as compared with the embodiment of Figs. Thus, the columnar body is provided for the purpose of softening the soil to be excavated and the like, and the number thereof is not particularly limited. In this case, the columnar body is preferably one having a pointed end, as shown in Fig. 4, in order to cut off the root between the columnar bodies.

In the embodiment shown in Fig. 5, the columnar bodies 5, 5 ', 5' 'and 5' '' shown in Fig. 4 are fitted in the ring. The shape of the ring is not particularly limited as long as the columnar body is fitted, and a polygonal ring is also used. By fitting the ring to the columnar body, further improvement of excavating force can be expected. In addition, the soil can be gathered near the air outlet by making the tip of the columnar body separate from the presence of the ring as shown in Fig.

The shape of the nozzle is not limited to these embodiments, but preferably has a nozzle having a shape as shown in Fig. 4 from the ease of insertion into the soil.

As the compressed air supply device, a device that is commercially available as a device for supplying (compressed) air from a general pressure of about 5 atmospheres to a pressure of about 30 atmospheres, such as a compressor, can be used as it is. Here, in a soil in which trees such as trees and trees are planted, vegetables, and houses in which fruits are grown, it is preferable to use compressed air of 150 to 80 L / min at a high pressure of about 10 to 25 atmospheres A compressed air supply device of, for example, about 20 kg, which is light in weight, is used.

The material to be connected to the compressed air supply device is not particularly limited as long as the pipe has a substantially straight shape (linear shape), and it is possible to withstand the high pressure from the inside, Materials are used. The length or outer diameter can be appropriately set according to the condition of the soil to be improved, but it is, for example, 90 to 160 cm in length and 6 to 10 mm in outer diameter.

A nozzle provided with a branching mechanism for compressed air is attached to the tip of the pipe on a substantially straight line with a substantially straight pipe. The attachment of the nozzle to the pipe can be performed in a state in which the nozzle can not be detached by welding or the like, but is preferably performed by a detachable attachment method, for example, a screw insertion method or the like. By making the nozzle detachable, the size of the nozzle can be appropriately changed according to the density of the roots from the vicinity of the root portion of the tree to the periphery thereof without replacing the entire pipe, and the substrate to be prepared can be made compact.

The connection between the pipe and the compressed air supply device is performed by using a tubular body such as a hose, preferably with a stopper for controlling the discharge of compressed air such as a ball cock.

The pipe behind the nozzle suppresses the scattering of soil scattered at the time of injecting the compressed air, so that a cover for preventing scattering of the soil can be provided. As such a cover, a stick-shaped one spreading in the nozzle direction and a rice air-shaped one having a flange portion toward the pipe tip end, preferably a rice air shape, are used. It is possible to prevent the soil from being scattered to the upper portion of any shape, but by using a cover for preventing soil scattering in the form of rice air, it is possible to prevent the soil from scattering in the lateral direction .

The soil remediation work using the soil remedying mechanism having the above configuration is carried out by repeating the operation of piercing the nozzle into the soil, spraying the compressed air using the compressed air supply device, and softening the soil near the nozzle of the nozzle tip All. At this time, the air discharged from the distributing mechanism is discharged to the ground through the side of the pipe, and a part of the soil softened together with the air is pushed up to the ground, thereby lowering the soil density in the ground.

(Example)

Next, the present invention will be described with reference to Examples.

[Example 1]

(The diameter of the nozzle of the nozzle shown in Fig. 1: 2.35 mm, the outer diameter of the pipe: 6.35 mm, the maximum diameter of the nozzle: 11.5 mm, the area of the circle calculated by taking the maximum outer diameter of the nozzle as the diameter, ) / Nozzle nozzle unit cross sectional area = 16.65) is approximately equal to a straight pipe, and a compressed air of 25 to 10 atmospheres pressure is supplied to the branch by using a Hitachi Koki air compressor EC1443H The soil improvement work was carried out and excavation was carried out up to 90 cm underground. It was confirmed that the drainage was remarkably improved compared to before the work when the plant was absorbed to the tree on the next day of the work.

[Example 2]

(The diameter of the nozzle of the nozzle shown in Fig. 3: 2.50 mm, the outer diameter of the pipe: 9.0 mm, the outer diameter of the nozzle: 15.0 mm, the area of the circle calculated with the nozzle outer diameter as the diameter, ) / Nozzle nozzle cross-sectional area = 23.04) was set on a substantially same straight line as the substantially straight pipe, a soil improvement operation was carried out in the same manner as in Example 1, and excavation was performed up to 50 cm underground. It was confirmed that the drainage was remarkably improved compared to before the work when the plant was absorbed to the tree on the next day of the work.

[Example 3]

(The diameter of the nozzle of the nozzle shown in Fig. 3: 2.50 mm, the outer diameter of the pipe: 9.0 mm, the maximum diameter of the nozzle: 20.0 mm (the area of the circle calculated with the nozzle outer diameter as the diameter, ) / Nozzle nozzle cross-sectional area = 51.04) was set on a substantially same straight line as the pipe having a substantially straight shape. The soil improvement operation was carried out in the same manner as in Example 1, and excavation was performed up to 50 cm underground. It was confirmed that the drainage was remarkably improved compared to before the work when the plant was absorbed to the tree on the next day of the work.

[Example 4]

(The diameter of the nozzle of the nozzle shown in Fig. 4: 2.50 mm, the outer diameter of the pipe: 9.53 mm, the outer diameter of the nozzle: 15.0 mm, the area of the circle calculated with the nozzle outer diameter as the diameter, ) / Nozzle nozzle cross-sectional area = 21.47) was used for soil improvement work as in Example 1 by using a soil improvement mechanism set on a substantially same straight line as a pipe of approximately linear shape. It was confirmed that the drainage was remarkably improved compared to before the work when the plant was absorbed to the tree on the next day of the work.

[Reference Example]

Using the nozzle shown in Figs. 1, 3 and 4, the soil improvement work of the tree was carried out from the gap of the root part protection plate, and the momentum (water wash) of the tree was checked after 5 months. . This point shows that soil improvement can be effectively performed by using the soil improvement mechanism according to the present invention.

(Industrial applicability)

The soil improvement device according to the present invention is widely used as a soil improvement device used in places where plants roots, such as a greenhouse for cultivating vegetables or fruits, houses, pots, .

One… pipe
2… Minute mechanism
3 ... Nozzle
4… home
5, 5 ', 5'',5''... Columnar body
6 ... ring

Claims (10)

1. A soil improving device for removing a compressed air from a nozzle and having a nozzle provided with a branching device for compressed air at a pipe leading end connected to a compressed air supply device for excavating the soil into a hole shape, (The area calculated from the diameter of the nozzle maximum outer diameter to the area calculated from the outer diameter of the pipe) / the area of the nozzle branching mechanism is 5 or more than the outer diameter of the pipe, and the straight pipe Wherein a nozzle located on the soil is used. The soil improvement device according to claim 1, wherein the nozzle end portion or both end portions have a tapered shape. 3. The soil improvement device according to claim 1 or 2, characterized in that the nozzle cross section is a columnar body, a cylinder shape, a circular shape, an elliptical shape or a polygonal shape. The soil improvement device according to claim 2, wherein the nozzle is formed by inserting a groove portion in the longitudinal direction. The soil improvement device according to claim 1 or 2, wherein a columnar member is disposed at the tip end of the nozzle, and a tip end of the columnar member extends forward beyond the branching point. The soil improvement device according to claim 5, further comprising a ring fitted to the tip of the columnar member. The soil conditioner according to claim 1, wherein the nozzle is detachable from the pipe body. The soil improvement device according to claim 1, wherein a cover for preventing the splashing of soil is provided on the pipe. A nozzle for use in the soil remediation apparatus according to any one of claims 1 to 3. A soil improvement method comprising: using the soil improvement apparatus according to claim 1 or 2 and spraying compressed air at a pressure of 10 to 25 atm using a compressed air supply apparatus.

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