KR102080758B1 - Artificial reef manufactured by 3D printers - Google Patents

Abstract

The present invention relates to an artificial reef manufactured by a 3D printer. Disclosed is an artificial reef manufactured by a 3D printer, comprising: a body having a columnar shape whose area increases toward a lower portion; a hollow unit formed inside the body; a plurality of through-holes formed at side surfaces of the body connecting the hollow unit with the outside of the body; and a reinforcement support formed on the hollow unit and supporting the inner side surface of the body.

Description

Artificial reef manufactured by 3D printers

The present invention relates to an artificial reef manufactured by a 3D printer, and has a complicated shape inside that cannot be manufactured by a form structure, which is suitable for aquatic organisms and has a structure capable of preventing natural settlement. It relates to an artificial reef manufactured by.

In general, artificial reefs are artificial structures installed in the sea to provide hideouts, habitats, or spawning sites for coastal fishes and marine fish and shellfish.

Such artificial reefs have been produced in the form of spherical and polyhedrons using concrete or steel, but recently, each of them can be achieved with the purpose of breeding seaweeds, breeding shellfish, infestation of fish, and the formation of vortices. It is designed and manufactured in a complex form.

These artificial reefs are massive gravitational structures produced by cemented materials such as mortar placed in formwork and cured for a period of time.

However, in the manufacture of the conventional artificial reefs, the formwork structure should be firmly constructed to support the side pressure of the flowable cementitious material until the cementitious material poured in the formwork is cured.

In addition, since artificial fish reefs must be clustered on the seabed to become habitats for aquatic organisms, a number of artificial fish reefs must be manufactured and supplied to the field. It takes a lot of effort and time to produce, which increases the cost of construction.

In addition, the artificial reefs manufactured by the formwork structure as described above has a problem that it is difficult to create a shape suitable for aquatic life because the shape of the artificial reef.

That is, the artificial reefs according to the conventional formwork have a problem in that it is difficult to complicate the shape of the artificial reefs because it is necessary to pour the cementitious material into the formwork and to remove the formwork from the cementitious material completely hardened after curing of the cementitious material. .

As such, since the interior of the artificial reef has a simple structure, there is a difficulty in forming the interior of the artificial reef, which is the main habitat for fish with high activity among the aquatic organisms.

In addition, since the conventional artificial reef manufactured by the form structure has a simple structure, the support can not be formed inside the artificial reef to reinforce the natural settlement of the artificial reef and there is a fear of collapse due to the natural settlement.

KR 10-1921622 B (2018.11.19)

The present invention is to solve the problems as described above, it is manufactured by a 3D printer having a structure that can be prevented from natural settlement by having a complex form inside that can not be manufactured by the form structure, and prevents natural settlement The purpose is to provide artificial reefs.

In addition, an object of the present invention is to provide an artificial reef manufactured by a 3D printer that can protect seaweeds from breakfast animals such as starfish, sea urchins, beatings by forming a plurality of irregularities on the surface to conceal the growth point of seaweeds. .

According to the technical idea of the present invention for achieving the above object, the body having a columnar shape of the lower light bar is manufactured by the 3D printer, the area increases toward the bottom, and the hollow portion formed inside the body; And a plurality of through-holes formed in the side of the body for communicating the outside of the hollow portion and the body, and a reinforcing support formed in the hollow portion and supporting the inner side of the body. Achieved by artificial reefs.

Here, the body is preferably formed with a plurality of irregularities on the surface.

In addition, the body has a polygonal pillar shape, the reinforcing support is preferably formed toward the bottom of the body from the boundary where the surface and the surface meets.

In addition, the reinforcing support is preferably formed such that the center of gravity of the body is located below the body.

In addition, the body is formed on both sides of the main support and the main support extending to the upper portion at a predetermined interval around the edge of the bottom and the bottom of the flat plate is placed on the bottom of the bottom is adjacent to the top of the main support It is preferable to include a side support which is integrally connected with the top and the bottom of the main support.

In addition, the side support is formed in the periphery of the first through hole and the first through-hole and the first through-hole and the marine life and the current is formed in the up and down direction of the side support and form a smaller opening area than the first through-hole It is preferable to include a 2nd through-hole.

In addition, the second through hole is preferably at least one of oval, circular, triangular.

In addition, the bottom portion is preferably formed with a third through-hole communicating the bottom surface and the hollow portion.

In addition, the body and the reinforcing support is a binder of 2.8 to 4.9% of the total volume of the mixture, 70.0 to 78.5% of the industrial by-product of the total volume of the mixture, 0.28 to 0.49% of the fiber for the concrete of the total volume of the mixture, the total volume of the mixture It is preferably configured to include 0.02 to 0.05% of admixture, 15.7 to 21.0% of the total volume of the mixture, and air as the remainder.

In addition, the concrete fiber is preferably made of one or two selected from polypropylene fibers, cellulose fibers.

In addition, the admixture is preferably a mixture of a thickening agent, a shrinkage reducing agent, a high fluidizing agent in a weight ratio of 1: 1: 1.

In addition, the industrial by-product is preferably configured by mixing the blast furnace slag and fly ash in a weight ratio of 1: 8-9.

According to the artificial reef manufactured by the 3D printer according to the present invention, the body has a columnar shape of the lower light bargain that the area increases toward the lower portion can be lowered the center of gravity of the body to ensure stability against the blue.

In addition, according to the present invention, the first through hole, the second through hole and the third through hole is formed in the body to smoothly supply oxygen to the inside of the body to assist in the habitat of aquatic life as well as the second through hole It has a smaller opening area than the first through hole, which not only serves as a hiding place for benthic creatures such as sea cucumbers and flounders, but also provides a hideout or spawning place for octopus, as well as habitats for abalone and sea urchins that prefer small gaps. Will be provided.

In addition, according to the present invention, a reinforcing support for supporting the main support constituting the body is formed in the hollow formed inside the body to prevent the natural settlement of the body as well as the reinforcing support lowers the center of gravity of the body to the blue It is possible to ensure the stability, and to form a gap between the main support and the reinforcement support and to provide an environment in which aquatic life can live in this gap.

In addition, according to the present invention, the body is manufactured by the 3D printer and when the body is formed by the 3D printer is naturally formed irregularities on the surface of the body to form a space for seaweeds to attach and inhabit abalone, turban Breakfast animals such as sea urchins are prevented from eating the growth points of algae, which prevents the melting of the algae.

In addition, according to the present invention, a third through hole is formed in the bottom constituting the body portion when the body is placed on the bottom surface part of the bottom surface is introduced into the hollow through the third through hole by the load of the body Since the bottom part can be buried in the sea bottom, the body can be stably fixed to the sea bottom to ensure stability against the blue.

1 is a perspective view showing an artificial reef manufactured by the 3D printer according to the present invention.
2 is a side view of FIG. 1.
3 is a plan view of FIG. 1.
4 is a cross-sectional view taken along the line AA of FIG.
5 is a perspective view showing another embodiment of an artificial reef manufactured by the 3D printer according to the present invention.
6 is a side view of FIG. 5.
7 is a bottom perspective view of FIG. 5.
8 is a cross-sectional perspective view of FIG. 5.

The terms or words used in this specification and claims should not be construed as being limited to the common or dictionary meanings, and the inventors can appropriately define the concept of terms in order to explain their invention in the best way. Based on the principle, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an artificial reef manufactured by the 3D printer according to the present invention, Figures 2 to 4 is a side view, a plan view, a side cross-sectional view of FIG.

Referring to the drawings, the artificial reef manufactured by the 3D printer according to the present invention is manufactured by a 3D printer, the body 100 having a columnar shape of the lower light bargaining area is increased toward the bottom, and the body ( Hollow portion 200 formed in the interior of the 100, and a plurality of through holes 300 and the hollow portion 200 formed on the side of the body 100 for communicating the outside of the hollow portion 200 and the body 100 It is formed of a) and consists of a reinforcement support 400 for supporting the inner surface of the body (100).

In other words, the body 100 is in the form of a column, and has a shape of a lower light cooperating area that increases in area toward the bottom, so that the center of gravity of the body 100 is located below. In addition, the body 100 is a hollow portion 200 is formed therein to become a habitat or hideout of aquatic life.

As described above, as the body 100 has a polygonal pillar shape of the lower beams, the center of gravity of the body 100 may be lowered to ensure stability against blue.

The body 100 has a polygonal pillar shape as shown in Figures 1 to 4, the body 100 is preferably composed of a bottom portion 110, the main support 120, the side support 130. .

The bottom 110 is formed in a flat shape so that the body 100 can be placed on the sea bottom. In addition, the main support 120 is in the form of a beam extending upwards at regular intervals around the edge of the bottom 110, when the main support 120 extends upward from the bottom 110 The overall shape of the body 100 is inclined toward the axis of the body 100 to have the form of a lower light reciprocation.

In addition, the upper end of the main support 120 inclined toward the axis of the body 100 as described above is connected to the upper end of the adjacent main support 120 is formed integrally, the top of the plurality of main support 120 The upper surface of the connected body 100 is formed with an opening 102 in communication with the hollow portion 200.

And, both sides of the main support 120 is formed with side support 130, the side support 130 is formed on both sides of the main support 120, the upper side of the main support 120 as described above the neighboring main It is connected integrally with the support 120. In addition, the side support 130 is integrally connected with the bottom 110 to support the main support 120.

As shown in FIGS. 1 to 4, the side support 130 has a form of sidewalls extending toward the top and bottom of the main support 120, respectively, and has a hollow portion 200 on the side support 130. ) And a plurality of through holes 300 to communicate the outside of the body 100 is formed.

The through hole 300 is preferably composed of a first through hole 310 and the second through hole 320, the first through hole 310 is a marine life and currents flow in and out of the upper and lower sides of the side support 130 Formed across the direction.

In addition, the second through hole 320 is formed around the first through hole 310 formed in the side support 130, the second through hole 320 is smaller than the opening area of the first through hole 310 Will form. At this time, the second through hole 320 is formed to have at least one of the shape of an oval, circular, triangular is formed to suit the habitat of aquatic life.

For example, when the second through hole 320 is formed around the first through hole 310 and formed into a triangle having an opening area smaller than that of the first through hole 310, benthic properties such as sea cucumber and flounder Not only does it serve as a shelter for creatures, but it also provides an octopus shelter or spawning ground, as well as a habitat for abalone and sea urchins that prefer small crevices.

As described above, the second through hole 320 may be formed in the top, bottom, left, and right sides of the first through hole 310, as shown in FIGS. As shown, the second through hole 320 may be formed only on the left and right sides of the lower portion with respect to the first through hole 310.

On the other hand, the reinforcing supporter 400 is formed inside the body 100, that is, the hollow part 200, to support the inner surface of the body 100. The reinforcing supporter 400 is formed toward the lower portion of the body 100 from the boundary where the face and the surface of the body 100 meets, such a reinforcing supporter 400 of the main supporter 120 as shown in FIG. The inner surface and the bottom portion 110 are integrally connected to support the main support 120 to prevent natural settlement of the body 100.

In addition, the reinforcement support 400 extends inclined toward the bottom 110 from the inner surface of the main support 120 so that the center of gravity of the body 100 is located below the body so that the center of gravity of the body 100 It is located at the bottom of the (100).

In this way, the reinforcing supporter 400 extends inclined toward the bottom 110 from the inner side of the main support 120 to integrally connect the main support 120 and the bottom 110 (main support ( The gap between 120 and the reinforcing supporter 400 is formed to provide an environment in which aquatic organisms can inhabit the gap.

In addition, the body 100 having the configuration as described above is formed with a concave-convex portion 101 is formed on the surface to form a space that can be inhabited by seaweeds, such as the concave-convex portion ( 101) is formed and the algae is attached to the growth point of the seaweed is located in the recessed portion of the concave-convex portion 101 to prevent breakfast animals such as abalone, conch, sea urchins, etc. to grind the growth point of the algae to prevent the mud recording Done.

On the other hand, the bottom portion 110 constituting the body 100, as shown in Figures 7 and 8, the third through hole 111 for communicating the bottom surface and the hollow portion 200 is formed. The third through hole 111 may be formed in various forms within a range that does not interfere with the connection of the reinforcing support 400 and the bottom 110.

As such, as the third through hole 111 is formed in the bottom portion 110, when the body 100 is placed on the sea bottom, a part of the sea bottom surface is loaded by the load of the body 100. Through the 111, the hollow portion 200 may be introduced into the bottom portion 110 so that the bottom portion 110 may be buried in the sea bottom so that the body 100 may be stably fixed to the sea bottom, thereby ensuring stability against the blue. .

On the other hand, the body 100 and the reinforcing support 400 is a binder of 2.8 ~ 4.9% of the total volume of the mixture, 70.0 ~ 78.5% of the industrial by-product of the total volume of the mixture, 0.28 ~ 0.49% of the concrete fiber And 0.02 to 0.05% of the total volume of the mixture, and 15.7 to 21.0% of the total volume of the mixture of water and air.

At this time, the binder may be composed of cement that is commonly used.

In addition, the industrial by-product may be composed of any one selected from fly ash, blast furnace slag fine powder having a latent hydraulic properties, or a mixture of two kinds. Preferably, the blast furnace slag and fly ash are mixed in a weight ratio of 1: 8-9. .

Fly ash is collected by the dust collector after the pulverized coal is burned in the furnace, and is distinguished from the bottom ash collected at the bottom of the boiler.

Fly ash does not have its own hydraulic properties but has the property of reacting with water and curing in the presence of alkaline substances, namely pozzolanic reactivity.

These fly ashes have a relatively slow initial reaction rate compared to cement, which may result in delayed setting and reduced initial strength.

High calcium fly ash produces less glass due to the burning of limestone and fossil fuels, which act as desulfurizers in circulating fluidized bed combustion (CFBC) boilers at relatively low temperature combustion conditions between 850 ° C and 900 ° C. In the form of non-uniform, pointed irregular form, especially calcium oxide and sulfur trioxide increase, these components combine to exist in the form of anhydrous gypsum, and the remaining calcium oxide components in the form of free-CaO after the reaction, relative Due to its low content of silicon dioxide, pozzolanic reactivity is lower than that of ordinary fly ash, while gypsum and free-CaO have self-hydrating power.

Table 1 below shows as an example the chemical composition of the high calcium fly ash obtained from a circulating fluidized bed combustion power plant.

Division (unit: weight%) SiO ₂ Al ₂ O ₃ Fe ₂ O ₃ CaO MgO SO ₃ Fly ash 21.45 10.20 12.37 25.32 2.12 19.57

Free-CaO content of the fly ash was measured by ASTM C 114 method, and the analysis was conducted by the Korea Institute of Ceramic Technology, an accredited test institute, and the free-CaO content was found to be 3.27% by weight.

Free-CaO, which is inherent in high-calcium fly ash, is responsive and accelerates initial congealing, which leads to destruction by exothermic, expansion and cracking.

However, when present together with blast furnace slag and cement, it becomes a necessary component for stimulation of blast furnace slag and formation of needle-shaped hydrates, which increases the initial reactivity of the binder and increases the restraint pressure due to expansion. have.

That is, in the present invention, the fly ash is contained in a large amount to increase the initial reactivity of the binder added in a small amount, and to increase the restraint pressure due to expansion, it is possible to form a support at an early stage.

The blast furnace slag powder is a sintered slag of hot molten state produced as a by-product of pig iron smelting after quenching with water, dried and pulverized. Since it is quenched and vitrified, it is mainly used as a cement admixture.

The blast furnace slag is effective in producing high strength concrete by reducing the hydration heating rate and suppressing the temperature rise of concrete, increasing the long-term strength, improving the watertightness, improving chemical resistance to sulfates, and suppressing alkali silica reaction. On the other hand, the initial strength is low, there is a concrete quality non-uniformity according to the quality non-uniformity of fine powder, it is known that the neutralization process is fast and the quality change is large depending on the curing temperature.

In general, blast furnace slag powder is not used to improve the quality of concrete but is mainly for cost reduction, and when cement replacement rate is lower than 30%, the purpose of hydration heat control such as mass or foundation concrete may be used. .

In the present invention, while suppressing the expression of long-term strength by minimizing the amount of blast furnace slag compared to fly ash, it is characterized by maintaining a high initial reactivity.

The following shows the chemical composition of the blast furnace slag used in the present invention, the specific gravity of the blast furnace slag powder was 2.85.

Division (unit: weight%) SiO ₂ Al ₂ O ₃ Fe ₂ O ₃ CaO MgO SO ₃ Blast furnace slag powder 30.57 11.20 0.45 45.32 2.22 2.54

When the industrial by-products are composed of blast furnace slag fine powder and high calcium fly ash in a weight ratio of 1: 8 to 9, the high calcium fly ash plays a role of gypsum, and the latent hydraulic reaction of the blast furnace slag fine powder is made smoothly. In addition to inducing a rapid reaction to, it is possible to easily separate and remove after formation of the support because a minimum amount of binder is used without the aggregate component.

Fiber for concrete is commonly used to increase the resistance to tensile, steel fibers or cellulose is mainly used.

To this end, the fiber used in the present invention is preferably made of any one selected from cellulose fibers, polypropylene.

Among the fibers, polypropylene fibers mainly play a role of increasing strength and are known to have no hygroscopicity.

Cellulose fibers, on the other hand, are hydrophilic fibers and have less strength than the polypropylene fibers, while being flexible and environmentally friendly.

In the present invention, the admixture is used together with the above-described components to reduce deformation due to flow in the 3D printer, shorten stabilization time, and help to increase strength.

To this end, in the present invention, the admixture is different from the admixture used in conventional concrete preparation, and it is preferable that the adjuvant, shrinkage reducing agent, and high fluidizing agent are mixed in a weight ratio of 1: 1.

Roughing agent is also called a hardening accelerator, and generally serves to increase the initial strength after casting and to quickly remove the formwork, and generally allows concrete to be poured in winter.

In the present invention, by using the coarseness to enable the casting in the winter season in the form of the support, the initial strength is increased, so that the mortar sprayed to the nozzle of the 3D printer is hardened quickly so that the spraying is sequentially performed in the 3D printer. Therefore, the formed shape can be prevented from being deformed by the flowability peculiar to mortar.

Examples of the coarse agent for this purpose may include calcium chloride, acetate, inorganic salts of nitrate, organic acid salts such as calcium silicate, and the like.

Shrinkage reducing agents are commonly referred to as expansion agents, and are used for the purpose of reducing cracks caused by shrinkage that occurs during the condensation and curing of thin concrete.

Shrinkage reducing agent in the present invention may be composed of a mixture of limestone and coke in a weight ratio of 1: 1 to 2.

The high fluidizing agent facilitates the construction of the mortar and the like, and the compaction through the nozzle, and increases the early strength.

As a high fluidizing agent, a lignin sulfonate type compound, a polymelamine sulfonate type compound, a polynaphthalene sulfonate type compound, a polycarboxylic acid type compound, etc. which are dispersing agents can be used individually or in mixture of 2 or more types.

That is, the high fluidizing agent increases the fluidity of the initial mortar so that the mortar can easily pass through the feed pipe and the nozzle inside the 3D printer, and the use of such a high softening agent reduces shrinkage due to shrinkage. And the mortar sprayed through the nozzle is cured quickly with the help of coarse to ensure that the shape is maintained smoothly.

According to the artificial reef manufactured by the 3D printer according to the present invention having the configuration as described above, the body 100 has a columnar shape of the lower beam cross-sectional area is increased toward the bottom to lower the center of gravity of the body 100 Stability against blue can be secured.

In addition, according to the present invention, the first through hole 310, the second through hole 320 and the third through hole 111 is formed in the body 100 to smoothly supply oxygen into the body 100. Not only helps to inhabit aquatic organisms, the second through hole 320 has a smaller opening area than the first through hole 310, and thus serves as a hideout for benthic creatures such as sea cucumber and flounder. It will provide an shelter or nesting ground for octopus, and a habitat for abalone and sea urchins that prefer small crevices.

In addition, according to the present invention, the reinforcing supporter 400 for supporting the main supporter 120 constituting the body 100 is formed in the hollow portion 200 formed inside the body 100 of the body 100 In addition to preventing natural settlement, the reinforcing supporter 400 lowers the center of gravity of the body 100 to secure stability against blue, and forms a gap between the main supporter 120 and the reinforcing supporter 400. These gaps provide an environment for aquatic life.

In addition, according to the present invention, the body 100 is manufactured by the 3D printer and when the body 100 is formed by the 3D printer, the uneven portion 101 is naturally formed on the surface of the body 100 to attach the algae In order to form a space for habitation, breakfast animals such as abalone, conch, and sea urchins are prevented from changing the growth point of the algae, thus preventing the mud recording.

In addition, according to the present invention, when the third through-hole 111 is formed in the bottom portion 110 constituting the body 100 when the body 100 is settled on the seabed surface by the load of the body 100 A portion of the surface may be introduced into the hollow portion 200 through the third through hole 111 so that the bottom portion 110 may be buried in the sea bottom so that the body 100 may be stably fixed to the sea bottom. Stability against blue can be secured.

Meanwhile, the present invention is not limited to the above-described embodiments, but may be modified and modified without departing from the scope of the present invention, and such modifications and variations should be regarded as belonging to the technical spirit of the present invention. .

100: body 101: irregularities
102 opening 110 bottom
111: third through hole 120: main support
130: side support 200: hollow part
300: through hole 310: first through hole
320: second through hole 400: reinforcing support

Claims (8)

Manufactured by 3D printer,
A body having a columnar shape of a lower light reciprocating body having an area increasing toward a lower portion thereof;
A hollow part formed inside the body;
A plurality of through holes formed in side surfaces of the body for communicating the hollow portion with the outside of the body; And
And a reinforcing supporter formed in the hollow part and supporting an inner surface of the body.
The body has a plurality of irregularities formed on the surface,
The body has a polygonal column shape, the reinforcing support is formed toward the bottom of the body from the boundary where the face and the face of the body,
The reinforcing support is formed such that the center of gravity of the body is located below the body,
The body is
A flat bottom portion placed on the sea bottom;
A main support extending upwardly at regular intervals around an edge of the bottom portion; And
A side support formed on both sides of the main support to integrally connect an upper end of the main support with an upper end of the neighboring main support and the bottom portion;
The side support is
A first through hole into which aquatic organisms and currents flow in and formed in a vertical direction of said side support; And
And a second through hole formed around the first through hole and forming an opening area smaller than that of the first through hole.
The second through hole is formed of at least one of oval, circular, triangular,
The bottom portion is formed with a third through hole for communicating with the bottom surface and the hollow portion,
The body and the reinforcing support are 2.8 to 4.9% of the total volume of the mixture, 70.0 to 78.5% of the industrial by-product of the total volume of the mixture, 0.28 to 0.49% of the concrete fiber, and 0.02 of the total volume of the mixture ~ 0.05% of admixture, 15.7 to 21.0% of the total volume of the mixture, and air as a balance,
The admixture is artificial reefs manufactured by 3D printer, characterized in that the adjuvant, shrinkage reducing agent, high fluidizing agent is mixed in a weight ratio of 1: 1. delete delete delete delete delete delete delete

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