KR20100026186A - Method for curing concrete in winter by a lamp - Google Patents

Abstract

PURPOSE: A concrete curing construction method during winter using a lamp is provided to reduce construction cost by reducing cost required for curing. CONSTITUTION: A concrete curing construction method during winter comprises following steps. Many latching parts are formed on a ceiling surface of a mold(20). A connecting cable(11) with a hook(12) formed on both sides and a power cable(13) with a connecting jack(14) are connected to both sides of a lamp(10). The lamps are positioned on the ceiling of the mold and a side wall at fixed intervals by latching the both hooks on the latching part. Power is applied through a power source cable by connecting a connection jack of the lamp which is adjacent to another lamp.

Description

Method for curing concrete in winter by luminaires {Method for curing concrete in winter by a lamp}

The present invention relates to a concrete curing construction method, and more specifically, because curing the concrete through a luminaire, to reduce the construction cost, to prevent the generation of toxic gas and waste, the luminaire to perform an equal curing construction work It relates to a winter concrete curing construction method using.

In general, concrete is a composite material composed of cement, water and aggregate, and has a characteristic of being hardened by the hydration reaction of cement and water.

Since the physical properties of the concrete vary depending on the curing method and the curing conditions, the curing in water (or water spray) at 20 ± 3 ° C is the standard, and is based on the strength of 28 days of age.

In addition, the hydration reaction of the concrete proceeds over a long period of time to express the required strength, because the hydration reaction itself is largely dependent on the temperature, when the outside temperature is low, the hydration reaction is delayed, so that the appropriate temperature during the initial hydration reaction It is very important to keep it.

In particular, concrete placed on the structure of reinforced concrete structures cannot exhibit its original performance unless the hydration reaction is realized through appropriate curing methods.In addition, in the early stages of concrete pouring, harsh concrete such as Seojung and Hanzhong When exposed to the environment or subjected to external forces such as vibration and shock, there is a risk that performance as the structure is degraded.

On the other hand, due to the deterioration of the performance of the concrete structure, it is necessary to specially manage the concrete that is installed in the cold season as cold-heavy concrete, and to insulate and cure concrete in areas where the outdoor temperature drops rapidly even if it is not in the cold region. In addition, the bleeding water should be removed and the surface should be covered with sheets to prevent freezing of the concrete.

In other words, when the temperature is below 0 ° C and the concrete is frozen, even if the temperature rises thereafter, the strength is significantly inhibited. When the temperature is below -10 ° C, the cement hydration reaction is actually stopped.

In addition, when the temperature reaches about -1 ° C, a large amount of free water freezes in the cement paste that is not yet hardened, and the volume expands by about 10%, thereby destroying the structure structure of the concrete and not having sufficient strength and durability even after the temperature rises. .

In addition, if the concrete undergoes rapid drying during curing, cracking may occur due to temperature stress, and if freeze-thawing is repeated, the concrete may be destroyed. Therefore, curing is necessary to ensure that the concrete does not fall below 0 ° C until it reaches a strength (5 MPa) that can withstand the East Sea.

Therefore, the proper curing plan of Korea-China concrete is to prevent the initial freezing of concrete and to secure the required strength in a predetermined age, and it is divided into initial curing and continuous curing. Among these, the initial curing is essential curing in Korea-China concrete, and the curing schedule and curing period are set according to the time when concrete is poured. The continuous curing is carried out at a lower temperature than the initial curing. Done.

Both the initial curing and the continuous curing of Korea-China concrete use the thermal curing method, and the thermal curing is divided into heat insulating curing and heat insulating curing.

First, thermal insulation curing is a method of preventing the temperature decrease of concrete by covering the surface of concrete with good thermal insulation materials such as sheets, mats, and insulation dies by using heat generated during the cement hydration reaction, mainly used when the outside air temperature is relatively low. do.

In addition, the heating insulation curing is a method of heating the concrete by installing a heat source, it is used in the case of insufficient heat insulation curing only insufficiently low outside temperature. In heat insulation curing, there is a method of heating a space with a heating device, a direct heating method of contacting a heat source with concrete with a heating sheet, and a method of warming a concrete surface by radiant heat such as an infrared heater.

Among them, the space heating curing method by a heating device such as lignite stove or hot air blower is most commonly used in the field because of the advantage that it can be heated and cured relatively easily.

1 is a conceptual diagram of curing concrete using lignite stove, and generates heat by burning lignite in the center of the room to be cured.

However, in the curing method using lignite stove or hot air fan, many harmful gases including carbon monoxide are released during combustion of lignite, causing environmental pollution. There was a very bad problem.

In addition, there is a problem that there is a problem that the temperature decrease due to wind caused by the wind is not installed to discharge the harmful gas in the field, which is a major obstacle to the curing of the concrete, and in the case of lignite stove, the electricity embedded in the floor There was also a concern that the piping could melt.

Furthermore, irregular heating and local heating due to the replacement of lignite or hot air fuel (kerosene) may cause partial temperature differences of 4 ~ 5 ℃ in the work site, especially on the ceiling and walls, depending on the heat source distance. There was a problem that it is difficult to expect and this may cause cracks due to dry shrinkage.

In addition, lignite or kerosene need to be replenished 3-4 times a day, so at night, additional personnel are needed for fuel replenishment and temperature management. In addition to being exposed to the risk of asphyxiation, there is also a risk of fire.

In particular, as shown in FIG. 2, the amount of burnt lignite for maintaining the minimum curing temperature of 5 ° C is considerable, and once used lignite is not reusable, and in the case of a hot air fan, expensive kerosene is used as a raw material, such as lignite or the like. The expenditure of construction cost increased due to soaring raw materials and oil prices. In addition, lignite generates a large amount of waste and dust during the combustion process, which incurs additional waste disposal costs, increasing construction costs, and cleaning dust. This cumbersome and pleasant working environment was fundamentally impossible.

On the other hand, Figures 3 and 4 are for the "construction method of the winter concrete structure" invented by the Republic of Korea Patent No. 0151943 to improve some of these problems, specifically, the heat insulation layer 2 to a predetermined thickness Forming the formwork (1) is formed, and is fixed to the reinforcement reinforcement (3) to be placed in the interior of the formwork (1) and tied in place with a binding line and install a heating wire (5) in a zigzag shape to connect the two end lines to the power source The concrete structure 6 is formed by connecting and pouring uncured concrete in the formwork 1.

That is, by transferring the heat generated from the twisted wire (5) to the concrete structure (6) through the reinforcing bar (3), it is possible to promote the curing of the uncured concrete.

However, the above-described prior art is very rare construction method that is very difficult to use practically, as well as the risk of electric shock due to the use of electric heating wire, a considerable cost is consumed in the purchase of electric heating wire.

The present invention has been made in order to solve the conventional problems as described above, because curing the concrete using an electric luminaire rather than a consumable fuel, the luminaire to reduce the cost required for curing to significantly reduce the construction cost To provide a winter concrete curing construction method using.

Another object of the present invention is to provide a concrete concrete curing construction method using a luminaire to block the generation of toxic gases and waste through the use of electric luminaires to create a pleasant working environment, and to realize environmentally friendly curing.

Another object of the present invention to provide a winter concrete curing construction method using a luminaire to ensure the operation stability by blocking the generation of harmful gases as described above.

Another object of the present invention to provide a concrete concrete curing construction method using a luminaire to maintain a constant heat source distance to perform an equal curing operation.

According to an aspect of the present invention, there is provided a construction method of curing concrete by applying heat to concrete placed between formwork, the method comprising: forming a plurality of hooking portions on a formwork ceiling surface; Connecting a power cable having a ring and a connection jack to each side of the luminaire; Arranging a plurality of luminaires at predetermined intervals on the formwork ceiling and sidewall surfaces by hooking both ends of the hook portion; It is characterized in that it comprises the step of connecting the connection jack of the luminaire and the neighboring luminaires with each other to apply power through a power cable.

Here, the luminaire uses a halogen lamp.

The present invention through the above problem solving means, by using the electric luminaire as a heating method for curing the concrete, to suppress the use of one-time materials such as lignite and kerosene, recycling the luminaire, it is possible to fundamentally suppress waste generation It becomes possible. Therefore, the cost used to purchase lignite or kerosene is reduced, labor costs required for lignite stove management, waste disposal costs, etc. are essentially unnecessary, thereby reducing the overall construction cost.

Furthermore, by heating and curing concrete using a luminaire as described above, the toxic gas emission factor due to lignite or kerosene is eliminated, thereby creating an environment-friendly and pleasant working environment, and also asphyxiation accident of workers due to toxic gas. In addition, it is possible to fundamentally solve the concern, to solve the risk of fire caused by lignite combustion, and to close the concrete in accordance with the need for no toxic gas discharge work, thereby maximizing curing efficiency. There is also an effect.

In addition, it is possible to maintain a constant heat source distance by providing the arrangement by adjusting the length of the arrangement of the luminaire through the adjustment of the length of the connection cable. Therefore, it is possible to perform an even heating curing operation, thereby there is an effect that can suppress the occurrence of cracking due to a partial temperature difference.

In addition, the target temperature can be adjusted according to the arrangement interval of the luminaire, and the heating temperature can be maintained higher, thereby overexpressing the early compressive strength of the concrete, thereby increasing the curing efficiency and air. There is also an effect that can be significantly shortened, and due to the multiple arrangement of luminaires, there is also an unnecessary effect that separate work lights are unnecessary.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

15 to 15 are for the concrete concrete curing construction method using the luminaire of the present invention, when specifically described with reference to Figures 5 to 7, first form a plurality of engaging portions 21 on the ceiling surface of the formwork (20) . That is, when the formwork 20 installed on the ceiling is made of a material such as aluminum, a plurality of catching holes are formed in the formwork 20 itself to form a catching portion 21. The catching hole is formed before the formwork 20; Afterwards, a plurality of left and right sides are formed at equal intervals.

And, if the formwork 20 installed on the ceiling is a plywood material to form a locking portion 21 by fixing the ring-shaped locking ring to the formwork 20, the locking ring is also the same as the above-mentioned locking hole ( 20, spaced apart at equal intervals before, after, left and right.

Subsequently, by hooking the luminaire 10 to the catching portion 21, the connecting cable 11 is connected to both sides of the luminaire 10, and the ring 12 is connected to the connecting cable 11, A power cable 13 is connected to supply the power to the luminaire 10, and the power jack 13 is connected to the power cable 13 of another neighboring luminaire 10 so as to be connected to each other. Equipped. Here, the lamp 10 may use an electric lamp 10 such as an incandescent lamp, a halogen lamp, an infrared lamp, a metal lamp, a heat lamp, etc., but using a halogen lamp in consideration of heat generation efficiency and product cost as shown in FIG. 8. It is appropriate.

In addition, the hook portion 21 is provided with a plurality of light fixtures 10 arranged at regular intervals on the ceiling and sidewall surfaces of the formwork 20 by hooking both hooks 12 connected to the light fixtures 10. That is, FIG. 7 is a photograph of various embodiments in which the luminaire 10 is installed. In the case where the luminaire 10 is to be disposed close to the ceiling, the connection cable 11 is short and the ring 12 is formed. By hanging on the locking part 21 of 20, the luminaire 10 is installed in the predetermined space | interval with the ceiling surface. Therefore, the concrete of the ceiling surface can be heated using the heat of the luminaire 10.

In addition, when the luminaire 10 is to be installed on the wall, the length of the connecting cable 11 is provided in accordance with the height to be arranged, and the hook 12 is hooked to the engaging portion 21 of the formwork 20. The lamp 10 is installed at a predetermined distance from the wall surface. Therefore, the concrete of the wall surface can be heated using the heat of the luminaire 10.

In this way, the length of the connecting cable 11 can be set appropriately by lengthening or shortening the length of the connecting cable 11 according to the position where the lighting device 10 is to be installed, and the position of the lighting device 10 can be freely changed and installed. By controlling the, it is possible to maintain a constant heat source distance and to adjust the target temperature.

And, by providing a short wire length of the power cable 13 and connecting to the relay outlet method through the power cable 13 and the connecting jack 14 of the neighboring luminaire 10, the installation of the power cable 13 is neat and simple Of course, the power supply is easy.

Subsequently, the power supply unit 13 is connected to the lamp 10 by connecting the power supply 13 to the lamp 10 by connecting the connecting jacks 14 of the other lamp 10 adjacent to each other and connecting the power cable 13 in a relay outlet method. To turn on the luminaire (10). Therefore, the concrete can be heated by generating heat in the luminaire 10, and through this, the concrete can be cured.

Referring to the operation and effect of the present invention configured as described in detail as follows.

Example 1

At the site A, the lignite stove and the lamp 10 were used for curing, and the temperature change over time was compared. As the luminaire 10, a 200W class halogen lamp was used, and the calorific value of the halogen lamp was 176 kW. And the front temperature of a halogen lamp is 200 degreeC, and the temperature of a back surface is 80 degreeC.

The temperature was measured using a thermometer at the same point based on the same area, and measured from 15:43 pm on the first day to 9 am on the third day.

9 is an experimental result of analyzing the temperature measured in this way, in the case of using the lignite stove was above 5 ℃ only in the day afternoon based on the minimum curing temperature of 5 ℃, the average time was maintained at 2 ℃.

On the other hand, in the case of using a halogen lamp, 11 ℃ was maintained after 1 hour after the installation of the halogen lamp, and the temperature of 14 ~ 15 ℃ was kept constant after rising to 16 ℃ by the temperature rise in the day of the second day.

That is, when the luminaire 10 is used, it can be confirmed that the minimum curing temperature as well as the temperature condition of 10 ° C., which is required for the prevention of initial freezing during concrete pouring, are satisfied.

Example 2

At the site B, the lignite stove and the lamp 10 were used for curing, and the temperature change over time was compared. As the luminaire 10, a 200W class halogen lamp was used, and the calorific value of the halogen lamp was 176 kW. And the front temperature of a halogen lamp is 200 degreeC, and the temperature of a back surface is 80 degreeC.

In the case of the lignite stove based on the same area, the temperature was measured using a thermometer at a distance of 1.5 m and 3.0 m, and was measured from 18 pm on the first day to 10 am on the second day.

10 is an experimental result of analyzing the temperature measured in this way, in the case of using the lignite stove, it can be seen that the difference in the temperature measured at the point where the 1.5 m and 3.0 m away from the lignite stove, respectively, the average occurs more than 5 ℃ In this case, it can be confirmed that the cracks due to dry shrinkage are increased because the temperature difference between concrete parts of the local heating furnace becomes remarkable.

On the other hand, when using a halogen lamp it can be seen that the temperature is kept constant to rise to 20 ℃. This temperature is the standard curing temperature for concrete, which is the best condition for strength development, which is hard to reach in winter curing.

Through the above experimental results, the curing construction method of the present invention using the luminaire 10, in particular, a halogen lamp not only exceeds the minimum curing temperature, but also exceeds the temperature of 10 ° C. required for preventing the initial east sea during the concrete placement. It can be confirmed that the temperature reaches 20 ° C which is difficult to maintain in the field.

Therefore, the heating using the luminaire 10 maintains the temperature about 3 times higher than the heating using the conventional lignite stove, thereby suppressing the occurrence of cracks due to the temperature difference generated in the concrete in winter as well as high strength in the early stage of concrete. At the same time, safety management is superior to lignite stove.

11 and 12 are experimental results showing the initial compressive strength when the lignite stove and the luminaire 10 are used in the site A and the site B, 92.5 ~ when compared to the standard strength of 24 MPa when the lignite stove is used. At 100%, areas below baseline strength require continuous observation.

On the other hand, when using the luminaire 10 of the present invention as compared to the reference strength of 24 MPa 97 ~ 117%, compared to the lignite stove, it can be seen that the early strength is expressed by about 9 ~ 13%, and thus the formwork (20) Early demolding is possible, which can drastically shorten the air.

In particular, FIG. 13 and FIG. 14 are experimental results showing the construction cost when using the lignite stove (or hot air fan) and the luminaire 10 during the first winter construction and the second winter construction. In the first winter season, the use of the luminaire 10 is about 35.8% higher than the lignite stove.

In addition, in the case of the secondary winter construction shown in FIG. 14, when the luminaire 10 is used, the luminaire 10 used in the primary winter construction can be reused, and thus the cost improvement effect of about 90% is achieved compared to using a hot air fan. You can check it.

In addition, Figure 15 is a graph comparing the amount of waste generated when using the lignite stove and the luminaire 10, when using the lignite stove 400 tons of waste is generated, while using the luminaire 10 of the present invention waste It is possible to create a pleasant working environment by zero generation, and is very excellent in terms of environmental management, and to reduce the cost of waste disposal.

On the other hand, the present invention has been described in detail only with respect to the specific examples described above it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, it is natural that such variations and modifications belong to the appended claims. .

1 is a conceptual view illustrating the installation of lignite stove used for conventional concrete curing construction;

2 is a construction cost analysis result graph according to the use of the existing lignite stove,

3 is a perspective view showing a winter concrete structure curing method according to the prior art,

Figure 4 is a cross-sectional view showing a winter concrete structure curing method according to the prior art,

5 is a conceptual view illustrating the installation of luminaires used for construction of winter concrete curing according to the present invention;

6 is a flow chart of installation of the luminaire according to the present invention;

Figure 7 is a photograph of the luminaire is installed according to the present invention,

8 is a graph showing a comparison of the various luminaires used by the present invention;

9 is a graph showing the curing of each construction at the site A using the luminaire and the existing lignite stove of the present invention, comparing the temperature change over time,

FIG. 10 is a graph showing curing conditions at the site B using the luminaire and the existing lignite stove of the present invention, and comparing the temperature change with time.

11 is a graph showing the comparison of the concrete compressive strength according to the use of the luminaire and lignite stove in the site A of Figure 9,

12 is a graph showing the comparison of the concrete compressive strength according to the use of the luminaire and lignite stove in the site B of FIG.

13 is a graph showing a comparison of the construction cost during the first winter construction by using the luminaire and the existing lignite stove of the present invention,

14 is a graph showing a comparison of the construction cost during the construction of the second winter season using the luminaire and the existing hot air blower of the present invention,

15 is a graph showing a comparison of the amount of waste generated by using the luminaire and the existing lignite stove of the present invention.

* Description of the major symbols in the drawings *

10: luminaire 11: connection cable

12: hook 13: power cable

14: connecting jack 20: formwork

21: catching part

Claims (2)

In the construction method of curing the concrete by applying heat to the concrete poured between the formwork, Forming a plurality of catches 21 on the ceiling surface of the formwork 20; Connecting the connecting cable 11 having the ring 12 to both sides of the luminaire 10 and the power cable 13 having the connecting jack 14; Hooking both hooks 12 to the catching part 21 and arranging a plurality of lamps 10 at regular intervals on the formwork 20 ceiling and sidewall surfaces; Winter concrete curing construction method using a luminaire, characterized in that the step of connecting the luminaire 10 and the connecting jack 14 of the neighboring luminaire 10 and applying power through a power cable (13). The method of claim 2, wherein the luminaire 10 is a concrete concrete curing construction method using a luminaire, characterized in that using a halogen lamp.

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