KR100869479B1 - Concrete - Google Patents

Abstract

An antimicrobial agent added concrete structure is provided to prevent corrosion of manhole generated from bacteria in the wastewater disposal. An antimicrobial agent added concrete structure comprises as follows. A diaphragm dividing inside and outside is set up in the space(12) of molds(10a,10b) manufacturing the concrete structure(20). In the mold outer space(16b), a concrete(18b) without the antimicrobial agent is injected. In the mold internal space(16a), a concrete(18a) in which the antimicrobial agent is mixed is injected. The diaphragm is separated from to the outside of the mold and it cures and the antimicrobial agent is distributed in the inner wall area that is weak in the corrosion and it completes.

Description

Concrete structure with antimicrobial agent and its manufacturing method {Concrete}

In order to prevent the corrosion of manholes caused by bacteria generated during sewage treatment, such as sulfur reduction bacteria and sulfur oxide bacteria, the present invention provides antimicrobial agents to produce concrete structures such as concrete manholes or pipes. It relates to an antimicrobial input concrete structure and a method of manufacturing the same.

In general, there is a problem that concrete structures such as concrete manholes or fume pipes are corroded by a large amount of hydrogen sulfide and sulfuric acid in concrete manholes or fume pipes as sewage treatment facilities.

Sulfur oxides such as thiobacilli and sediment in sewage pipes and sulfur reduction bacteria such as desulfovivibrio are used to dissolve sulfates and sulfur in the sewage and finally sulfuric acid is generated. And calcium sulfate are produced by the reaction, and the calcium sulfate is reacted with tricalcium aluminate (C ₃ A) in the hardened body to produce Ettringite, which reduces the strength of concrete structures and pipelines, resulting in shortened lifespan. .

Conventionally, in order to solve such a problem, a method of incorporating organic pharmaceutical agents such as thiabendazole, nickel metal, and antimicrobial metal ion-supported inorganic powders having antibacterial activity to sulfur-reducing bacteria was incorporated into the concrete composition.

The addition of antimicrobial metal ion-supported inorganic powder to concrete is a useful technique that has a growth control effect on not only sulfur oxidizing bacteria but also sulfur reducing bacteria and carboxylic acid producing bacteria. However, in order to impart a predetermined strength to the concrete structure, it is necessary to adjust the mixing ratio of cement, aggregate, and water included in the concrete composition within a predetermined range. Because of this, there is a problem that it is impossible to sufficiently add the amount of the antimicrobial metal ion-supported inorganic powder necessary to give growth inhibition effect of bacteria to the concrete structure to the concrete composition.

In addition, silver carbonate, silver compounds selected from the group consisting of silver oxide and silver phosphate, copper compounds selected from the group consisting of copper carbonate, copper oxide, copper phosphate and copper hydroxide, ethylenediamine-4-acetate, trinitro-3-acetate, Antimicrobial agent for concrete was prepared by mixing ion support compound selected from the group consisting of tripolyphosphate and hexametaphosphate at a mass ratio of 0.1 to 2.0: 0.5 to 2.5: 10 to 60. By adding 0.8 to 1.5 mass% A method of producing concrete products has been proposed.

These antimicrobial agents are expensive and act as a disadvantage of increasing the product cost. In particular, since the antimicrobial agent is added to the concrete to be manufactured and then used to mix, a large amount of antimicrobial agent is required, so that the cost of the product will increase.

The present invention was devised to solve the above-mentioned conventional problems, and its object is to produce an expensive antimicrobial agent in the manufacture of concrete structures such as manholes or sewer pipes, and the inner walls of the manholes or sewer pipes which are expected to be corroded by sulfuric acid. By focusing on the same fragile part, it is possible to provide a low-cost antimicrobial-injected concrete structure by obtaining high efficiency even with a small amount of antimicrobial agent.

The present invention for achieving the above object, in the introduction of the antimicrobial agent in the concrete structure,

The plate is installed in the space of the mold for manufacturing the concrete structure and divides the inside and the outside, and the general concrete is put into the mold outside space, while the plate mixed with the antimicrobial agent is mixed into the mold inside space. This is achieved by separating the mold into the outside to concentrate the antimicrobial agent on the inner wall, which is susceptible to corrosion.

In addition, the present invention, in the injection of the antimicrobial agent in the concrete structure, while applying a release agent for smooth demoulding of the product to the inner mold of the mold for manufacturing the concrete structure, after mixing the antimicrobial agent to the mold release the concrete in the mold The antimicrobial agent included in the release agent is achieved by permeating the concrete inner wall surface.

The present invention has the advantage of achieving a concrete structure excellent in the corrosion protection effect by the antimicrobial agent at a low cost because the antimicrobial agent is concentrated in the part where the corrosion is weak when manufacturing the concrete structure.

In addition, even in the installation of the manhole cover on the upper part of the concrete structure, the height adjustment can be freely adjusted, there is an advantage that the manhole cover can be easily installed according to the height of the road surface.

Embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart of manufacturing an antimicrobial concrete structure according to the present invention.

The mold shown in the drawing is a mold for manufacturing the concrete structure 20 of the present invention, in particular, a mold for manufacturing a concrete manhole. The mold is composed of inner and outer molds 10a and 10b_, and a space 12 is formed between the inner and outer molds 10a and 10b, in which the concrete 12 is to be poured. The space 12 has the shape of the concrete structure 20.

Although the illustrated mold shows a simple and general mold structure, this is only an embodiment, and the shape or structure of the concrete structure 20 may be changed as necessary.

An important configuration for the mold is to have a partition 14 in the space 12 between the inner / outer molds 10a and 10b. The partition wall 14 serves to ensure that one body is formed when the concrete 18 and 18b separated by the partition wall 14 are joined to each other after curing.

After setting such a mold, the partition 14 is provided in the space 12 formed between the inner / outer molds 10a and 10b. Here, the interior divided by the partition 14 is generally set to the side where the cause of corrosion is provided, such as sewage, and the outside is set to the side where there is no fear of corrosion.

Therefore, in the interior space 16a of the partition 14, concrete 18a mixed with an antibacterial agent (metal ions (Ag, Cu, Zn, etc. + inorganic carrier (zeolite)) is poured, and the external space of the partition 14 Concrete 8b, in which antimicrobial agent is not administered, is poured in 16b.

When the concrete is poured in this manner and the partition 14 is lifted and separated from the manhole before curing, the concrete 18 and 18b separated by the partition 14 are joined to each other, and the partition 14 is formed. The boundaries by are mixed with each other. However, this only mixes the boundaries, not the whole. Therefore, the inside of the antimicrobial agent is maintained as it is. In this state, when the concrete 18, 18b is cured, the internal / external molds 10a and 10b are removed, and the removed concrete structure 20 (manhole on the drawing) has an antimicrobial agent injected into the concrete inside. It becomes concrete.

2 is a flowchart of manufacturing an antimicrobial concrete structure 20 according to another embodiment of the present invention.

As shown in FIG. 2, a mold for manufacturing the concrete structure 20 is illustrated, which also includes an inner / outer mold 10a and 10b.

The characteristic of manufacturing the antimicrobial concrete structure 20 with such a mold is to apply a release agent to easily separate it from the mold after the concrete poured in the mold is cured, by putting an antimicrobial agent on the mold release surface (10a) It is applied to. Here, the mold applying the release agent to which the antimicrobial agent is applied is called the inner mold (10a) simply because the inside is in contact with the source of concrete corrosion, such as a concrete manhole or sewage pipe. A mold release agent with an antibacterial agent is applied to a mold surface on which a face is formed.

In this way, when the release agent in which the antimicrobial agent is applied is applied to the surface of the inner mold 10a and the concrete is poured, the antimicrobial agent included in the release agent penetrates into the concrete contacting the release agent, and eventually the release agent is applied to the surface of the inner mold 10a. It will soak in.

When the concrete is cured in this state and separated from the mold, the concrete structure 20 including the antimicrobial agent may be obtained only on the surface where the corrosion causes contact.

Figure 3 is a flow chart manufacturing antimicrobial concrete structure according to the third embodiment of the present invention.

As shown in the drawing, a reinforcing bar t is installed in a space between the inner mold 10a and the outer mold 10b for manufacturing a concrete structure, and the space is divided inside or outside of the reinforcing bar t. The mesh m is provided. The mesh (m) is a mesh (m) having an eye of a size that delays the flow of concrete.

When pouring concrete into the concrete structure manufacturing mold, the concrete mixed with the antimicrobial agent is injected into the inner space divided by the mesh (m), and the general concrete without the antimicrobial agent is added to the outer space of the mesh (m). Antibacterial concrete and concrete are separately put in separate spaces divided by reinforcing bars (t) and mesh (m), but the concrete at the boundary is distributed and mixed through the eyes of the mesh (m) It becomes a structure. Curing concrete in such a state is to obtain a concrete structure in which the antimicrobial agent is distributed only on the inner wall vulnerable to corrosion.

Figure 4 is an exploded perspective view of the structure to couple the height adjustable manhole cover to the present invention antimicrobial concrete structure, Figure 4 is an exploded perspective view showing a manhole cover installation structure to the present invention antimicrobial concrete structure, Figure 5a, 5b is the present invention Side cross-sectional view of a first embodiment showing a structure for installing a manhole cover on an antibacterial concrete structure.

As shown in the drawings, when the concrete structure 20 is a concrete manhole, the upper part of the concrete structure 20 has an opening 22 through which a person can enter and exit. The manhole cover 30 is provided.

The opening 22 of the concrete manhole is provided with a connection bolt for fixing the manhole cover 30 to be installed later.

The mounting structure of the connecting bolt is formed as a fixing means for coupling the connecting bolt 42 to the upper surface of the opening 22 of the manhole as shown in Figure 4 is coupled to the connecting bolt 42 is moved to the fixing means Will be. In this case, the fixing means, in particular, the bolt fixing means, as shown in Figure 4 includes a plurality of grooves 23 on the corresponding surface of the opening 22, the manhole cover 30 is seated and coupled, A support plate 24 including a bolt head insertion groove 25 and a position adjustment groove 26 connected thereto is installed at an upper portion of the groove portion 23, and a position adjustment groove 26 is disposed at a lower end of the connection bolt 42. It is configured to form a bolt head 44 to be caught. At this time, the structure of the bolt hole 34 of the arc-shaped long hole form formed in the flange 32 of the manhole cover 30, and the positioning groove 26 of the support plate 24, concrete manhole and manhole cover 30 The manufacturing error occurs when manufacturing the), so as to ensure a smooth assembly by absorbing the error of each other when the height adjustment device is combined. And the number of each of the connecting bolts 42 is suitable at least three and the arrangement is preferably to form an equilateral triangle structure. In addition, the support plate 24 is formed on the side or bottom anchor pins that are planted in the concrete structure 20 to be integrated with the concrete structure 20.

In addition, a fastening nut 48 for firmly fixing the connecting bolt 42 and the manhole cover 30 to the opening 22 of the manhole through the connecting bolt to install the manhole cover 30 using the fixing means is provided. Is further configured.

When fixing the manhole cover 30 to the opening 22 of the manhole through the above structure, the connection bolt 42 to the bolt head insertion groove 25 of the support plate 24 provided in the opening of the manhole provided as shown in FIG. After inserting the bolt head 44 of the) to move it to the positioning groove (26). In this way, the bolt head 44 is locked to the position adjusting groove 26 so as not to fall upward. In this state, the manhole cover 30 is coupled to the connection bolt 42. That is, the upper end of the connecting bolt is matched with the bolt hole 34 of the arc-shaped long hole structure formed on the flange 32 around the manhole cover 30, and then the tightening nut 48 is tightened to tighten the upper end of the connecting bolt. It is fixed. If the position of the connection bolt 42 and the bolt hole 34 of the flange 32 does not match well, move and tighten the connection bolt 42 before adjusting the tightening nut 48.

In this state, if the top of the manhole cover 30 and the road surface are paved side by side as shown in Figure 5b, the installation of the manhole is completed, and the height of the manhole cover can be adjusted in anticipation of the increase in the road surface due to the road repair in the future. You must leave room. To this end, the cap (C) is put on the upper end of the connecting bolt 42 to protect the thread of the tightening nut 48 or the connecting bolt 42 by the packaging material.

On the other hand, if you need to cover the road to repair the road by the long time use of the manhole circumference (asphalt, concrete, etc.) after removing the cap (C) covered on the top of the connecting bolt 42. Then, the tightening nut 48 is removed and the manhole cover 30 is lifted up.

And a connection nut 43 and another connection bolt 42 and a spring that is elastically installed around the connection bolt, fastening the connection nut 43 to the upper end of the connection bolt 42 previously installed as shown in FIG. 5B. do. Hereafter, after the other connection bolt 42 is fastened to the upper portion of the connection nut 43, a spring 46 is installed around the connection bolt 42.

The manhole cover 30 or the new manhole cover 30 lifted in this state is seated on the upper part of the connecting bolt 42 or the spring 46. That is, the upper end of the connecting bolt 42 is inserted through the bolt hole 34 of the flange 32 around the manhole cover 30, and then tighten the tightening nut 48 to the upper end thereof. By the tension of the spring 46, the manhole cover 30 is stopped in a state in which the spring is slightly compressed only by the weight. At this time, the adjustment operation for matching the upper end of the manhole cover 30 according to the height of the road surface, that is, to adjust the tightening degree of the tightening nut 48 is performed. If the height is too high, tighten the tightening nut 48 to adjust the height by lowering the manhole cover 30, and if the manhole cover 30 is too low, loosen the tightening nut 48 to compress the spring 46. Lift the manhole cover 30 by tension to adjust the height.

In this state, if the pavement is overlaid, the road surface and the upper end of the manhole cover 30 can be aligned side by side.

Figure 6a, 6b, 6c is a side cross-sectional view of a second embodiment showing a structure for installing a manhole cover in the present invention antimicrobial concrete structure.

As shown in the figure, the opening 22 of the manhole is integrally formed with a connection bolt 42 for fixing the manhole cover 30. When the manhole is manufactured, the manhole and the connection bolts 42 are integrated by planting the bottom of the connection bolts 42 in concrete and curing.

As shown in FIG. 6A, the connecting bolts 42 fixing means plant a plurality of anchor nuts 24 ′ when manufacturing a concrete manhole on a corresponding surface of the opening 22 to which the manhole cover 30 is seated and coupled thereto. The connecting bolt 42 may be configured to be screwed.

The method of installing the manhole cover 30 in the manhole in which the connection bolt 42 is installed is the same as that shown in FIGS. 5A and 5B, and the structure thereof is as shown in FIGS. 6A, 6B and 6C.

As shown in the drawing, an anchor nut 24 'is provided in the opening 22 of the manhole. That is, when manufacturing the manhole, the anchor nut 24 'is planted and installed on the upper surface of the opening 22 in which the manhole cover 30 is seated.

As described above, in the method of installing the manhole cover 30 in the manhole in which the connection bolt 42 is installed, the manhole cover 30 is inserted by inserting the upper end of the connection bolt 42 into the bolt hole 34 of the manhole cover 30. After seating in the opening 22 of the manhole, the tightening nut 43 is fastened and fixed.

When overlaying for road repair, the height of the manhole cover 30 should be increased by the overlay height, which is installed by adjusting the height in the same manner as in FIGS. 5A and 5B. The same is omitted.)

7A, 7B, and 7C are side cross-sectional views of a third embodiment showing a structure in which a manhole cover is installed in an antimicrobial concrete structure of the present invention, and FIG. 8 is a state diagram of an anchor nut before manhole cover installation of FIG. 7A.

As shown in the drawing, an anchor nut 24 'is provided in the opening 22 of the manhole. That is, when manufacturing the manhole, the anchor nut 24 'is planted and installed on the upper surface of the opening 22 in which the manhole cover 30 is seated.

As such, the method of installing the manhole cover 30 in the manhole in which the anchor nut 24 'is installed is performed by fastening the connecting bolts 42 to the anchor nut 24', and the upper end of the bolt hole of the manhole cover 30. Insert 34 into the manhole cover 30 seated in the opening 22 of the manhole, and then tighten and tighten the tightening nut 48 to install. Then, the cover bolt (c) on the top of the connection bolt 42 may be packed with a packaging material.

If the cover is covered for repairing the road surface, the perimeter of the manhole cover 30 is removed, and then the cover c is removed and the manhole cover 30 is lifted up. Then, the connecting bolts 42 fastened to the anchor nut 24 'are screwed back to draw the upper portion of the anchor nut 24'. Therefore, after installing the spring 46 around the height of the connection bolt (42), the height of the connection bolt 42 is inserted into the bolt hole 34 of the manhole cover flange (32) to the manhole cover 30 It rests on the top of the spring 46.

Subsequently, the tightening nut 48 is fastened to the upper end of the connecting bolt 42, and the height of the manhole cover 30 may be appropriately adjusted by adjusting the tightening degree.

If the length of the connection bolt 42 is insufficient, the length of the manhole by extending the length by connecting the connection nut 43 to the upper end of the connection bolt 42, and connecting another connection bolt 42 on the top What is necessary is just to adjust the installation height of the cover 30.

On the other hand, Figure 7 is a stopper (c ') is fitted to the upper end of the anchor nut (24'). This is to prevent foreign matter from penetrating into the anchor nut 24 ′ from the outside before installing the manhole cover 30.

1 is a flow chart manufacturing antimicrobial concrete structure according to Example 1 of the present invention.

Figure 2 is a flow chart manufacturing antimicrobial concrete structure according to the second embodiment of the present invention.

Figure 3 is a flow chart manufacturing antimicrobial concrete structure according to the third embodiment of the present invention.

Figure 4 is an exploded perspective view showing a manhole cover installation structure in the present invention antimicrobial concrete structure.

Figure 5a, 5b is a side cross-sectional view of a first embodiment showing a structure for installing a manhole cover in the present invention antimicrobial concrete structure.

Figure 6a, 6b, 6c is a side cross-sectional view of a second embodiment showing a structure for installing a manhole cover in the present invention antimicrobial concrete structure.

Figure 7a, 7b, 7c is a side cross-sectional view of a third embodiment showing a structure for installing a manhole cover in the present invention antimicrobial concrete structure.

Figure 8 is a state of processing of the anchor nut before the manhole cover installation of Figure 7a.

*** Explanation of symbols for the main parts of the drawing ***

10a, 10b-Internal / External Mold 12-Space 14-Bulkhead

16a, 16b-Interior / exterior space 18a- Concrete mixed with antibacterial agents

18b-concrete without antibiotics 20-concrete structure

22-Opening 23-Groove 24-Support Plate

24 '-Anchor nut 25-Bolt head insertion groove 26-Moving groove

30-Manhole cover, 32-Flange 34-Bolted

40-Height adjuster 42-Connecting bolt 44-Bolt head

46-Spring 48-Tightening nut t-Reinforcing bar

m-mesh

Claims (12)

In manufacturing the concrete structure 20 into which the antimicrobial agent is added, a mold release agent mixed with an antimicrobial agent is applied to the internal mold 10a among the molds for manufacturing the concrete structure 20, and concrete is introduced into the space 12 of the mold. Method of producing a concrete structure, characterized in that the antimicrobial agent contained in the release agent soaked into the concrete inner wall after pouring. Among the molds for manufacturing the concrete structure 20 into which the antimicrobial agent is added, an antimicrobial agent is mixed and applied to a mold release agent applied for smooth demoulding of the product to the internal mold 10a, and the concrete is poured into the mold to prevent the antimicrobial agent contained in the release agent. An antimicrobial input concrete structure that was cured after permeating the concrete inner wall surface. The method of claim 2, An opening 22 formed at an upper portion of the concrete structure 20 A manhole cover 30 installed in the opening 22 by a lid and a base on which the lid is seated, A plurality of connecting bolts 42 having one end penetrating through the bolt hole 34 of the manhole cover flange 32 and the other end connected to the opening 22 of the concrete manhole; Fixing means for fixing the lower end of each connecting bolt 42 to the opening 22 of the concrete manhole, The fastening nut 48 which is fastened to the upper end of the bolt penetrating the bolt hole 34 of the manhole cover 30 to fix the manhole cover 30 to the concrete manhole with its tightening force structure. The method of claim 3, wherein the bolt fixing means, the manhole cover 30 includes a plurality of grooves 23 on the corresponding surface of the opening 22 is seated and coupled, the upper portion of each groove 23 A support plate 24 including a bolt head insertion groove 25 and a position adjustment groove 26 connected thereto is inserted into the bolt head insertion groove 25 at a lower end of the bolt and the position adjustment groove ( 26) The concrete structure, characterized in that formed by the bolt head 44 to be locked. According to claim 3, The bolt fixing means, when manufacturing a concrete manhole on the corresponding surface of the opening 22 to which the manhole cover 30 is seated coupling a plurality of anchor nuts (24 ') to the connection bolt Concrete structure, characterized in that 42 is screwed. 4. The concrete structure according to claim 3, wherein the bolt hole (34) of the manhole cover (30) is an arc-shaped long hole. The concrete structure according to claim 3, wherein the bolt fixing means is integrally formed by planting a lower end of the connecting bolt (42) when manufacturing the concrete structure (20). The connection of claim 3, wherein the spring 46 is elastically installed around the bolt between the manhole cover 30 and the opening 22 of the concrete manhole, and passes through the bolt hole 34 of the manhole cover 30. Concrete structure, characterized in that the fastening nut (48) is fastened to the upper end of the bolt (42) to adjust the height according to the tightening degree. delete delete delete delete

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