KR20120082559A - Exchange type reduction device of concrete temperature gap by means of pipe cooling, exchange type reduction method using the device and structure using the method - Google Patents

Abstract

PURPOSE: A device for reducing a concrete temperature difference using pipe cooling technology when concrete is cured, a curing method for reducing a concrete temperature difference using the same, and a structure cured thereby are provided to prevent internal cracks by reducing the temperature difference between the inside and the outer surface of a concrete structure. CONSTITUTION: A device for reducing a concrete temperature difference using pipe cooling technology when concrete is cured comprises a main water tub(100), pipes(120), hoses(300), an auxiliary water tub(700), supply pipes(710), and a control unit(600). The main water tub stores cooling water. The pipes are connected to the main tub through a concrete structure. The stored cooling water is supplied to the inside the pipes, and the internal temperature of the concrete structure is reduced. The auxiliary water tub stores heating water. The supply pipes are connected to the auxiliary water tub and supplies the heating water to the outer surface of the concrete structure when the internal temperature of the concrete structure is less than a set specific temperature.

Description

Convertible concrete temperature difference reduction device using pipe cooling technology during concrete curing, Convertible concrete temperature difference reduction curing method using the device and structure cured by the method {Exchange Type Reduction Device of Concrete Temperature Gap by means of Pipe Cooling, Exchange Type Reduction Method using the Device and Structure using the Method}

The present invention relates to a conversion type concrete temperature difference reducing device using pipe cooling technology during concrete curing, a conversion type concrete temperature difference reduction curing method using the device, and a structure cured by the method. More specifically, at least one pipe is provided in the interior of the poured mass concrete (concrete structure), and a hose having a hole formed in the outer surface is installed to cool the inside, and at the same time, the outer surface is heated to interior the concrete structure. A device that reduces the temperature difference between the external surface and the external surface, and stops the supply of cooling water to the pipes provided inside the concrete structure in the middle of curing, and supplies the heated water to the outside of the concrete structure by the supply pipe, thereby reducing the temperature difference more efficiently. , Methods and structures cured by such methods.

Concrete cures concrete mixtures of cement, sand, gravel, and water, and is used as an important material in civil engineering or building structures because it resists natural winds such as water, fire, and earthquakes.

Such concrete is produced in a batch plant and transported to a concrete truck called a ready-mixed concrete, which is then poured into a concrete structure to be compacted and cured. The batch plant kneads the concrete every time by weighing the amount of concrete dough into a mixer, discharging the fully kneaded concrete, and then adding new concrete dough.

When concrete is cured, hydration is accompanied by hydration, which is a phenomenon in which solute molecules or ions attract several water molecules around them to form one molecular group, thus forming one molecular group. Hydration heat is generated in the process.

The heat of hydration increases the internal temperature of the concrete structure, and as a result, a temperature difference occurs inside and outside the concrete structure, causing a temperature crack. Such temperature cracking inevitably occurs during curing, because the internal temperature is increased by the heat of hydration, and the internal and external temperature difference of the concrete structure is 30 ° C. or more. In addition, in addition to the temperature cracking caused by the temperature difference between the inner and outer surfaces, there is also a dry shrinkage crack generated when the outer surface is dried and contracted during the curing process of the concrete structure.

Figure 1a is a graph showing the temperature and temperature difference between the inner and outer surfaces of the concrete structure according to the curing time. It takes about 12 to 15 days to complete curing. The internal temperature is increased to about 90 ° C according to the heat of hydration, and the maximum temperature difference with the internal temperature is about 60 ° C or more. Therefore, cracks are generated in the cured structure having such a temperature difference.

In particular, in the middle temperature (暑 中) where the temperature of the outside air is greatly increased, the hydration heat is also increased along with the increase of the outside temperature, and the temperature crack of the concrete structure may be more severely generated. Therefore, in the art, various measures such as material measures, construction measures, and structural measures are used as measures to reduce temperature cracking. In particular, during the summer season, concrete measures such as pre-cooling by ice plants are used. Cooling) and pipe cooling are used, and another method is to install a pipe on the outside to spray water on the external surface to wet the external surface.

The former pre-cooling is to immerse sand or gravel in ice water and then mix it with cement or to spray cold coolant on aggregate or sand. The latter pipe cooling involves placing pipes at regular intervals inside the structure before concrete is poured and then placing concrete. And curing the concrete while circulating the cooling water in the pipe to lower the internal temperature of the concrete.

FIG. 1B schematically illustrates a method of spraying water on the outer surface 20 of the concrete structure 10 by installing a pipe 30 outside the conventional concrete structure 10. As shown in FIG. 1B, water is wetted to the outer surface 20 of the concrete structure 10 through the pipe 30 to prevent dry shrinkage cracks generated during dry shrinkage. However, such a method prevents dry shrinkage cracks, and there is a problem that cracks due to the temperature difference between the outer surface 20 and the inside still occur.

1C schematically illustrates a temperature difference reducing device by a conventional pipe 30 cooling method. As shown in FIG. 1C, the coolant 60 is stored in the water tank 100, and the coolant 60 is supplied to the pipe 30 installed inside the concrete structure 10 by a pump (not shown). Therefore, the cooling water flows into the concrete structure, thereby cooling the inside of the concrete structure. By cooling the inside of the concrete structure 10, the temperature difference between the outer surface 20 and the inside is reduced.

However, the pre-cooling has a problem that the ice plant equipment is complicated and the cost is increased, the precise temperature control is not possible, and only the pipe cooling only reduces the internal temperature, the internal and external temperature reduction effect is less than the present invention. Has a problem.

Therefore, the present invention has been made to solve the above problems, to reduce the temperature cracking of the concrete, to simplify the equipment to reduce the cost, accurate temperature control, easy construction and easy temperature crack reduction method and reduction It is an object to provide a device.

 Proposed conversion temperature cracking reducing device and method by installing a plurality of holes in the outer surface of the concrete structure by installing a hose that can discharge the heating water by gravity without a separate driving power to heat the outer surface and at the same time Cooling water flows through the pipes provided inside the curing system while reducing the temperature difference between the external surface temperature of the concrete structure and the internal temperature due to the heat of hydration of the concrete structure.

In addition, when the internal temperature of the concrete structure is lower than a specific temperature (for example, about 50 ° C.) in the middle stage of curing, the supplied cooling water is no longer heated, and thus the external surface of the concrete structure cannot be heated efficiently, It is possible to provide a conversion type reduction apparatus and a method which can reduce the temperature difference more efficiently by separately supplying the heating water to the outer surface through the or the like.

In addition, the heated water is made possible by efficiently heating the entire external surface through the hose hole. Efficient heating of the outer surface is made possible by the curing cloth covering the entire outer surface and the insulating member covering the curing cloth.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments in conjunction with the accompanying drawings.

An object of the present invention is to assemble the reinforcing bars, install the formwork to pour concrete into the interior of the formwork, temperature difference reduction device generated in the concrete structure formed by the poured concrete, the main water tank stored in the cooling water; It is installed inside the formwork, embedded in the concrete structure by pouring the concrete, penetrates the concrete structure and is installed to be spaced apart from each other at a predetermined interval, connected to the main water tank and the cooling water stored in the main water tank is supplied to the interior, An internal temperature of the structure is reduced, and a pipe for heating the cooling water supplied therein to output heating cooling water; A hose connected to an output end of each pipe, installed on an outer surface of the concrete structure, supplied with cooling coolant output from the pipe, and having a plurality of holes on the outer surface thereof, and discharging the heated cooling water into the hole; An auxiliary water tank with heated water stored therein; A supply pipe connected to the auxiliary water tank to supply the heated water to an external surface when the internal temperature of the concrete structure becomes lower than a predetermined temperature; And a controller for supplying cooling water from the main water tank to the pipe when the internal temperature of the concrete structure is higher than a specific temperature, and supplying heating water to the supply pipe from the auxiliary water tank below the specific temperature. It can be achieved as a conversion concrete temperature difference reduction device using the pipe cooling technology.

The output end of the supply pipe is provided between the pipe and the hose, when the internal temperature of the concrete structure is below a certain temperature, further comprises a conversion valve configured to block the supply of cooling water, and supply the heating water to the hose by the supply pipe It may be characterized by.

At least one hose is installed on the outer surface of the concrete structure, and the heating coolant or the heating water discharged from the hole flows to the outer surface, and is connected to the water collecting duct and the water collecting duct installed on the side of the concrete structure to be heated. It further includes a recovery pipe for recovering the cooling water or the heating water to the water tank, or formed in the corner portion of the concrete structure and the ground contacting, connected to the cooling water or the water channel and the channel to the heating water collected on the outer surface and the heating cooling water Or a recovery tube for recovering the heating water into the water tank, or heating water or heating to the main water tank through the recovery pipe and the recovery pipe connecting the position where the flowing heating water or the cooling water is collected and the main water tank. It may be characterized in that it further comprises a recovery pump for recovering the cooling water. .

A first pump provided between the main water tank and the pipe to supply the cooling water to the pipe; and a second pump provided between the auxiliary water tank and the supply pipe to supply the heating water to the supply pipe. Can be.

It may be characterized in that it further comprises a curing cloth which is installed on the outer surface and absorbs the heated cooling water or a portion of the heating water discharged from the hole to absorb the heated cooling water or heating water to the outer surface.

It may be characterized in that it further comprises a heat retaining member covered for the curing cloth to heat the heated cooling water or the heating water absorbed in the curing cloth.

The insulating member may be characterized in that the vinyl canvas or bubble sheet.

The auxiliary water tank may further include heating means for heating the heated water stored in the auxiliary water tank.

It further comprises a surface temperature sensor provided on the outer surface to measure the temperature of the outer surface and a central temperature sensor provided inside the concrete structure to measure the internal temperature of the concrete structure, the control unit is connected to the heating means, When the power is supplied and the internal temperature measured by the central temperature sensor is below a certain temperature, the conversion valve is operated to block the heating coolant supplied from the pipe to the hose, and to control the supply of heating water from the supply pipe to the hose. can do.

It may be characterized in that it further comprises a connection pipe provided between the main tank and the auxiliary tank to supply the cooling water stored in the main tank to the auxiliary tank.

The control unit may control the first pump to adjust the flow rate of the cooling water supplied to the pipe, and the second pump to control the flow rate of the heating water supplied to the hose.

When the controller calculates the temperature difference between the outer surface and the inside of the concrete structure and the temperature difference is greater than or equal to the preset temperature difference, the controller may operate the first pump to supply the cooling water to the pipe.

As another category, an object of the present invention is to assemble the reinforcing bar and formwork, install at least one pipe inside the formwork, and install the pipe to penetrate the concrete structure formed by pouring concrete in the formwork; Install at least one hose having a plurality of holes on the outer surface of the concrete structure, connect each end of the pipe with the hose, connect each end of the pipe with the main tank for storing the cooling water therein, and the heating water inside Installing a supply pipe for supplying the auxiliary water tank and the heating water to the outer surface of the concrete structure to store the; Installing a water collecting duct on the side of the concrete structure or installing a water channel at a corner portion of the concrete structure and the ground contacting with the water; Generating a temperature difference between the inner and outer surfaces of the concrete structure and supplying the cooling water stored in the main water tank to the pipe by the first pump; Cooling the inside of the concrete structure by the cooling water supplied to the pipe, and cooling water is heated to supply the cooling water to the hose; Heating cooling water is supplied to the hose, the heating cooling water is discharged through the hole, and the outer surface is heated, and the heating cooling water is collected in a water channel or a water collecting duct and recovered through the recovery pipe to the main water tank; When the internal temperature of the concrete structure is lower than the predetermined temperature, the control unit stops the operation of the first pump to cut off the supply of cooling water supplied by the pipe, and operates by supplying the second pump installed between the supply pipe and the auxiliary water tank. It can be achieved as a conversion-type concrete temperature difference reduction curing method comprising a; supplying the heated water to the outer surface of the concrete structure by the pipe.

The supply pipe installation step may further include installing a conversion valve between the pipe and the hose, and connecting the conversion valve and the supply pipe. The heating water supply step may include: The operation of the conversion valve to cut off the supply of the cooling water supplied by the pipe, and supplying the heating water to the hose by the supply pipe; may be characterized in that it further comprises.

The installation step further includes the step of installing the curing cloth on the entire outer surface,

In the discharging step, the curing cloth may be characterized by absorbing a portion of the heated water discharged from the hole.

After the curing step installation, it may be characterized in that it further comprises the step of installing a thermal insulation member on the curing cloth.

The control unit may further include supplying power to heating means installed in the auxiliary water tank, thereby heating the heating water.

The controller adjusts the flow rate of the cooling water supplied to the pipe,

It may be characterized by adjusting the flow rate of the heating water supplied to the supply pipe.

The control unit calculates the temperature difference between the external surface and the internal surface by the external surface temperature measured by the surface temperature sensor installed on the external surface and the central temperature sensor installed inside the concrete structure and the internal temperature of the concrete structure. When the temperature difference is greater than the preset temperature, the first pump may be operated.

Before the heating water supplying step, a connection pipe may be installed between the main water tank and the auxiliary water tank to supply the cooling water stored in the main water tank to the auxiliary water tank.

After curing of the concrete structure is completed, grouting the inside of the pipe may be characterized in that it further comprises.

Another object of the present invention can be achieved as a concrete structure cured by the concrete temperature difference reduction curing method.

Thus, according to one embodiment of the present invention as described above, by installing a hose having a plurality of holes on the outer surface of the concrete structure to increase the temperature of the outer surface of the concrete structure, and at the same time, to the pipe installed inside the concrete structure As the coolant flows, it has an effect of cooling the inside of the concrete structure. Therefore, it is possible to reduce the temperature between the inside and the outer surface of the concrete structure to prevent the internal crack due to the temperature difference.

In addition, when the internal temperature of the concrete structure is lower than a specific temperature (for example, about 50 ° C.) in the middle stage of curing, the supplied cooling water is no longer heated, and thus the external surface of the concrete structure cannot be heated efficiently, By separately supplying the heating water to the outer surface through, for example, there is an effect that can reduce the temperature difference more efficiently.

In addition, by increasing the external surface temperature to reduce the temperature difference between the inside and the outside surface of the concrete structure to prevent internal cracking due to the temperature difference, because the heating coolant or the curing water absorbing the heating water is always in contact with the external surface, The surface can be heated efficiently, and the surface can be prevented from cracking due to dry shrinkage.

And, according to one embodiment of the present invention, by further comprising a heat insulating member on the curing cloth, there is an effect that can increase the heating efficiency of the external surface by maintaining the temperature of the heating water for a long time. In addition, the hose having a hole is installed in the concrete structure, the naturally flowing heating water is collected in such a water recovery duct is collected and circulated back to the tank through the recovery pipe to achieve the object of the present invention with a relatively low power. It has the advantage of being able to.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be appreciated by those skilled in the art that various other modifications and variations can be made without departing from the spirit and scope of the invention, All fall within the scope of the appended claims.

Figure 1a is a graph showing the external surface temperature and the internal temperature and the temperature difference of the concrete structure while the poured concrete is curing,
Figure 1b is a schematic diagram of a device for preventing dry shrinkage cracks by spraying water on the outer surface using a conventionally installed pipe,
Figure 1c is a schematic diagram of a temperature difference reducing device is installed a pipe pipe flowing cooling water in the conventional concrete structure,
2 is a perspective view of a conversion type concrete temperature difference reducing apparatus according to a first embodiment of the present invention;
3A is a cross-sectional view taken along line AA ′ of FIG. 2;
3b is a plan view of a conversion type concrete temperature difference reducing apparatus according to a first embodiment of the present invention;
Figure 4 is a block diagram showing the signal flow of the conversion type concrete temperature difference reducing apparatus according to the first embodiment of the present invention,
5 is a flowchart of a method for reducing the conversion type concrete temperature difference according to the first embodiment of the present invention;
FIG. 6 is a graph illustrating an external surface temperature, an internal temperature, and a temperature difference graph according to curing time according to the conversion type concrete temperature difference reduction method according to the first embodiment of the present invention.
7 is a perspective view of a conversion type concrete temperature difference reducing apparatus according to a second embodiment of the present invention;
8 is a plan view of a conversion type concrete temperature difference reducing apparatus according to a second embodiment of the present invention;
9 is a block diagram showing a signal flow of a conversion type concrete temperature difference reducing apparatus according to a second embodiment of the present invention;
10 is a flowchart illustrating a method for reducing the conversion type concrete temperature difference according to the second embodiment of the present invention.

With reference to the accompanying drawings will be described in detail a preferred embodiment that can be easily implemented by those skilled in the art to which the present invention pertains. However, in describing in detail the operating principle of the preferred embodiment of the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In addition, the same reference numerals are used for parts having similar functions and functions throughout the drawings. Throughout the specification, when a part is 'connected' to another part, this includes not only 'directly connected' but also 'indirectly connected' with another element in between. do. In addition, "including" any component does not exclude other components unless specifically stated otherwise, it means that may further include other components.

< In the first embodiment  Configuration of the abatement device Reduction Method >

Hereinafter will be described the configuration of the concrete temperature difference reducing apparatus according to the first embodiment of the present invention. First, Figure 2 shows a perspective view of the concrete temperature difference reducing apparatus according to the first embodiment of the present invention. As shown in FIG. 2, the concrete temperature difference reducing device may include a hose 300 installed at an upper surface of the outer surface 20 of the concrete structure 10, a pipe 120 passing through the interior 50 of the concrete structure 10, In the main water tank 100, the first pump 110, the water recovery duct 400, the curing cloth 200, the thermal insulation member 210, the recovery pipe 130, the interior 50, the cooling water 60 is stored Auxiliary water tank 700, the second pump 730, the supply pipe 710 for supplying the heating water 61, the heating water 61 is stored, the connection pipe connecting the main water tank 100 and the auxiliary water tank 700 740, a third pump 750, and a controller 600.

As shown in FIG. 2, the pipe 120 is embedded and penetrated through the interior 50 of the concrete structure 10. Pipe 120 is installed in the formwork before placing concrete, it is embedded in the interior 50 of the concrete structure (10). Pipe 120 is connected to the main water tank 100 for storing the coolant (60). Water is supplied to the main water tank 100, and a predetermined amount of cooling water 60 is stored. In addition, a first pump 110 is provided between the pipe 120 and the main water tank 100, and the cooling water 60 stored in the main water tank 100 is supplied to the pipe 120 by the first pump 110. do.

The coolant 60 stored in the main water tank 100 is supplied into the pipe 120 by the first pump 110. The coolant 60 supplied to the pipe 120 is heated by the internal temperature of the concrete structure 10. That is, in the initial stage of curing, the internal temperature of the concrete structure 10 is about 60 ~ 100 ℃, the temperature of the cooling water 60 is about 0 ~ 30 ℃, so that the cooling water 60 is heated by mutual heat transfer, concrete The structure interior 50 is to be cooled.

The coolant 60 is heated by the temperature of the concrete structure 50 to be supplied to the hose 300 as the heating coolant. The coolant 60 stored in the main water tank 100 is supplied to the pipe 120 by the first pump 110, and the controller 600 controls the first pump 110 to supply the cooling water 60, The flow rate in the pipe 120 is adjusted. That is, the first pump 110 may be configured as an inverter pump and controlled by the control signal of the controller 600. The coolant 60 is supplied to the pipe 120 to have a flow rate that can increase the mutual heat exchange efficiency between the coolant 60 existing inside the pipe 120 and the inside of the concrete structure 50. In addition, the flow rate of the cooling water 60 in the pipe 120 determines the temperature of the heating coolant supplied to the hose 300. The controller 600 adjusts the flow rate of the coolant 60 in the pipe 120 such that the temperature of the heated coolant supplied to the hose 300 is about 40 ° C. to 70 ° C.

The hose 300 is connected to each of the pipes 120, and at least one is provided on the outer surface 20 of the concrete structure 10. In a specific embodiment, as shown in Figure 2, the end of the hose 300 is provided as a closed portion, a plurality of holes 310 are formed on the outer surface. Therefore, the heating coolant supplied to the hose 300 may be discharged through the hole 310 of the hose 300. As shown in FIG. 2, the hose 300 is provided on the upper upper outer surface 20 of the concrete structure 10. Accordingly, the heating coolant discharged through the hose hole 310 naturally flows down the outer surface 20 toward the lower side by gravity.

In addition, the concrete temperature difference reducing apparatus according to the first embodiment of the present invention includes a water recovery duct (400). As shown in Figure 2, the water recovery duct 400 is provided on one side of the bottom of the concrete structure (10). Alternatively, instead of the water recovery duct 400, a water channel may be configured between the lower portion of the concrete structure 10 and the ground to refer to the heating coolant. Therefore, the heated cooling water is collected in the water recovery duct 400, and is recovered to the main water tank 100 again through the recovery pipe 130.

The outer surface 20 of the concrete structure 10 is heated by the heating coolant discharged by the hose hole 310. That is, since the temperature of the heating coolant is about 40 to 70 ° C., and the outer surface 20 of the concrete structure 10 is about 10 to 30 ° C., the outer surface 20 is heated by the heating coolant. Thus, the interior 50 of the concrete structure 10 is cooled, and at the same time the outer surface 20 of the concrete structure 10 is heated to reduce the temperature difference between the interior 50 and the outer surface 20.

And, during curing, when the internal temperature of the concrete structure 10 is below the set specific temperature (for example, about 50 ℃), the cooling water 60 is no longer supplied to heat the outer surface 20 You won't be able to. Therefore, when the internal temperature of the concrete structure 10 is below a predetermined temperature (for example, about 50 ° C.), the controller stops the operation of the first pump 110 to cool the water 60 to the pipe 120. The supply will be cut off. The control unit 600 operates the second pump 730 to supply the heated water 61 stored in the auxiliary water tank 700 to the outer surface 20 of the concrete structure 10 through the supply pipe 710. do.

As shown in Figure 2, the auxiliary water tank 700 is provided with a heating means 500, and maintains the stored heating water 61 at a temperature of about 40 ~ 70 ℃. Therefore, the heated water 61 stored in the auxiliary water tank 700 is supplied to the outer surface 20 of the concrete structure 10 through the supply pipe 710 so that the outer surface of the concrete structure 10 by the heated water 61. 20 is to be heated. In addition, a connection pipe 740 may be further included between the auxiliary water tank 700 and the main water tank 100. Accordingly, the cooling water 60 stored in the main water tank 100 is supplied to the auxiliary water tank 700, and the cooling water 60 is heated by the heating means 500 provided in the auxiliary water tank 700 to heat the heating water 61. It may be configured to be supplied to the outer surface 20 of the concrete structure 10 by the supply pipe 710.

3A is a cross-sectional view taken along the line A-A 'of FIG. As shown in FIG. 3A, a pipe 120 is provided in the interior 50 of the concrete structure 10. The pipe 120 penetrates the inside of the concrete structure 50. Therefore, the coolant 60 supplied to the pipe 120 flows to cool the inside 50 of the concrete structure 10. As shown in FIG. 3A, the hose 300 is located on the upper upper outer surface 20 of the concrete structure 10. Therefore, the heating coolant 60 discharged through the hose hole 310 naturally flows downward along the outer surface of the concrete structure 10, and the heated cooling coolant is collected into the water recovery duct 400. And, as shown in Figure 3a, the outer surface 20 of the concrete structure 10 is provided with a curing cloth 200. In addition, the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting between the position and the main water tank 100 where the flowing cooling water is collected without separately installing the water recovery duct 400. It may also be configured to include a recovery pump (not shown) for recovering the heating coolant.

Curing cloth 200 is provided with a surface material such as a nonwoven fabric. Therefore, a part of the heating coolant discharged from the hose hole 310 is absorbed by the curing cloth 200. Therefore, since the curing cloth 200 absorbing the heating coolant is always in contact with the outer surface 20 of the concrete structure 10, the heating coolant is always in contact with the outer surface 20 of the concrete structure 10. . The temperature of the heating coolant discharged by the hose hole 310 corresponds to about 40 to 70 ° C. In addition, the outer surface 20 of the concrete structure 10 is heated to approximately 10 to 30 ° C. by the heating coolant discharged to the outer surface 20.

In addition, a surface temperature sensor 71 and a central temperature sensor 72 are provided on each of the outer surface 20 and the inside 50 of the concrete structure 10. The central temperature sensor 72 installed in the concrete structure 50 is installed in the formwork before pouring concrete. Accordingly, the control unit 600 is disposed between the outer surface 20 and the inside 50 by the temperature sensor 71 installed on the surface portion temperature sensor 71 installed on the outer surface 20 of the concrete structure and the inside of the concrete structure 50. We can calculate the temperature difference of. In addition, the temperature of the heating coolant may be controlled by controlling the flow rate of the cooling water 60 supplied to the pipe 120 by controlling the first pump 110 based on the calculated temperature difference.

Curing cloth 200 is installed to increase the heating efficiency. As the curing cloth 200 comes into contact with the outer surface 20, the heating coolant discharged into the hose hole 310 continuously comes into contact with the outer surface 20 without gaps, and thus the outer surface 20 of the concrete structure 10 more quickly. Will be heated. In addition, the curing cloth 200 and the hose 300 is covered by the insulating member 210. The heating water 61 is kept warm by covering the heat insulating member 210 on the curing cloth 200. That is, the heating efficiency can be increased by maintaining the temperature of the heating water 61 for a longer time. The thermal insulation member 210 may be provided with a vinyl canvas, a bubble sheet, and the like having a thermal insulation effect.

And, during curing, when the internal temperature of the concrete structure 10 is below the set specific temperature (for example, about 50 ℃), the cooling water 60 is no longer supplied to heat the outer surface 20 You won't be able to. Therefore, when the internal temperature of the concrete structure 10 is equal to or less than a predetermined temperature (for example, about 50 ° C.), the control unit 600 stops the operation of the first pump 110 to the pipe 120. The cooling water 60 is cut off. The control unit 600 operates the second pump 730 to supply the heating water 61 stored in the auxiliary water tank 700 to the outer surface 20 of the concrete structure 10 through the supply pipe 710. do.

The auxiliary water tank 700 is provided with a heating means 500, and maintains the stored heating water 61 at a temperature of about 40 ~ 70 ℃. Therefore, the heated water 61 stored in the auxiliary water tank 700 is supplied to the concrete structure outer surface 20 through the supply pipe 710 so that the outer surface 20 of the concrete structure is heated by the heating water 61. do.

Figure 3b is a plan view of a conversion type concrete temperature difference reducing apparatus according to a first embodiment of the present invention. As shown in FIG. 3B, the coolant 60 stored in the main water tank 100 is supplied to the pipe 120 provided in the concrete structure 50 by the first pump 110. The controller 600 controls the first pump 110 to adjust the flow rate of the coolant 60 supplied to the pipe 120. In the initial curing step, the cooling water 60 flowing in the pipe 120 is heated, and the inside of the concrete structure 50 is cooled.

The cooling water 60 heated in the pipe 120 is supplied to the hose 300 as the heating coolant, and the heating coolant supplied to the pipe 120 is discharged to the hole 310 formed in the hose 300. As shown in FIG. 3B, the heated cooling water discharged into the hole 310 naturally flows down to the water recovery duct 400.

In addition, as described above, the curing cloth 200 covers the outer surface 20, and the outer surface 20 of the concrete structure 10 is heated by the heating coolant absorbed by the curing cloth 200. Then, the thermal insulation member 210 is included on the curing cloth 200, thereby maintaining the temperature of the heating cooling water for a longer time. As shown in Figure 3b, the heating and cooling water collected in the water recovery for 400 is recovered to the main water tank (00) back to the recovery pipe (130). In addition, further comprising a recovery pump for recovering the heating cooling water to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting the position and the main water tank 100 where the flowing cooling coolant is collected. It may be configured to.

And, during curing, when the internal temperature of the concrete structure 10 is lower than the set specific temperature (for example, about 50 ℃), the cooling water 60 is no longer supplied to heat the outer surface 20 You won't be able to. Therefore, when the internal temperature of the concrete structure 10 is lower than the predetermined temperature (for example, about 50 ° C.), the controller stops the operation of the first pump 110 and cools the water 60 to the pipe 120. ) Will cut off the supply. In addition, the controller operates the second pump 730 to supply the heated water 61 stored in the auxiliary tank 700 to the outer surface 20 of the concrete structure 10 through the supply pipe 710.

As shown in Figure 3b, the auxiliary water tank 700 is provided with a heating means 500, and heats the stored heating water 61 to a temperature of about 40 ~ 70 ℃. Thus, the heated water 61 stored in the auxiliary water tank 700 is supplied to the concrete structure outer surface 20 through the supply pipe 710 and the outer surface 20 of the concrete structure 10 by the heated water 61. Will be heated. The heated water 61 supplied to the outer surface 20 is absorbed by the curing cloth and flows down to collect in the water duct 400. Then, it is recovered to the main water tank 100 again through the recovery pipe 130 connected to the water recovery duct 400. In addition, to recover the heated water 61 to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting between the position where the heated water 61 flowed down and the main water tank 100. It may be configured to further include a recovery pump to recover the heated water 61 to the main water tank (100). In addition, a connection pipe 740 is provided between the main water tank 100 and the sub water tank 700, and the cooling water 60 is supplied to the sub water tank 700 to the main water tank 100, and to the sub water tank 700. The heated water 61 heated by the installed heating means 500 is circulated while being supplied to the outside of the concrete structure 10 through the supply pipe 710.

4 is a block diagram showing a signal flow by the control unit 600 of the conversion type concrete temperature difference reducing apparatus according to the first embodiment of the present invention. The conversion type concrete temperature difference reducing device includes a central temperature sensor 72 provided at the center of the inside 50 of the concrete structure 10 and a surface temperature sensor 71 configured at the outer surface 20. Therefore, the control unit 600 receives the temperature of the interior of the concrete structure 50 from the central temperature sensor 72, and receives the temperature of the external surface 20 from the surface temperature sensor 71 and receives the internal 50 and the external surface 20. The difference between the temperature is calculated in real time.

When curing of the concrete structure 10 is started and the temperature becomes more than a predetermined temperature difference by the heat of hydration, the controller 600 operates the first pump 110 to supply the cooling water 60 to the pipe 120.

In addition, the temperature sensor may be provided inside the pipe 120, inside the supply pipe 710, and inside the hose 300. Accordingly, the temperature sensor detects the current temperature of the pipe 120, the internal temperature of the supply pipe 710, and the temperature of the heating coolant flowing in the hose 300. The controller 600 controls the first pump 110 to control the pipe 120 based on the temperature difference between the inside of the concrete structure 50 and the outside surface 20, the inside temperature of the pipe 120, and the temperature of the heating water 61. Adjust the flow rate of the cooling water (60) supplied to. The flow rate of the cooling water 60 flowing inside the pipe 120 determines the temperature of the heating cooling water.

In addition, the control unit supplies power to the heating means 500 provided in the auxiliary water tank 700, and heats the heating water 61 to 40 ~ 80 ℃, based on the internal temperature of the concrete structure 10, The flow rate of the heated water 61 supplied through the pipe 710 is controlled.

The controller does not operate the second pump 730 when the internal temperature of the concrete structure 10 becomes higher than a predetermined temperature (for example, 50 ° C.), but when the temperature falls below a specific temperature, the first pump The operation of the second pump 730 is stopped. Therefore, the supply of the cooling water 60 through the pipe 120 is stopped, and the second pump 730 is controlled to supply the heating water 61 to the outer surface 20 of the concrete structure through the supply pipe 710. .

Hereinafter, a first embodiment of the concrete temperature difference reduction method of the present invention will be described. First, Figure 5 shows a flowchart of a method of reducing the conversion type concrete temperature difference according to the first embodiment of the present invention. Rebars are assembled and formwork is installed. Then, the pipe 120 is installed in the formwork. In addition, temperature sensors 71 and 72 may be installed inside the formwork. Then, the concrete is poured into the formwork to form the concrete structure 10 (S10-1).

Then, one end of each of the pipes 120 is connected to the main water tank 100 in which the coolant 60 is stored, and the other end is connected to the hose 300. The hose 300 connected to the pipe 120 is installed on the outer surface 20 of the concrete structure 10 (S20-1). As described above, the end of the hose 300 is blocked, a plurality of holes 310 are formed on the outer surface. And, the hose 300 is installed on the outer surface 20 of the concrete structure (10).

As the curing of the concrete structure 10 starts, the temperature difference between the inner structure 50 and the outer surface 20 of the concrete structure is generated by the heat of hydration of the concrete (S30-1). Temperature sensors 71 and 72 installed on the outer surface 20 and the inner surface 50 of the concrete structure 10 measure the temperature of the outer surface 20 and the inner 50. The controller 600 calculates the temperature difference in real time by the temperature of the outer surface 20 of the concrete structure 10 and the temperature of the inside 50 detected by the temperature sensors 71 and 72.

The controller 600 determines a supply speed of the cooling water 60 supplied to the pipe 120, that is, a flow rate of the cooling water 60 flowing in the pipe 120 based on the calculated temperature difference. As described above, the flow rate of the cooling water 60 flowing in the pipe 120 determines the temperature of the heating coolant supplied to the hose 300. Therefore, the flow rate of the cooling water 60 supplied to the pipe 120 based on the temperature difference calculated in real time may be adjusted in real time by the controller 600.

In addition, the controller 600 controls the first pump 110 to supply the coolant 60 into the pipe 120 at the set flow rate (S40-1). The coolant 60 supplied into the pipe 120 flows into the pipe 120 and is heated. That is, in the initial curing step, the cooling water 60 supplied to the pipe 120 has a temperature of about 0 ~ 30 ℃, the temperature of the interior 50 of the concrete structure 10 corresponds to about 70 ~ 100 ℃ The interior 50 of the concrete structure 10 is cooled by the cooling water 60 (S50-1). At the same time, the cooling water 60 supplied to the pipe 120 is heated. The heated cooling water 60 is supplied to the hose 300 as the heating coolant (S60-1). As described above, the temperature of the heating coolant supplied to the hose 300 is determined by the temperature of the interior 50 of the concrete structure 10 and the flow rate of the cooling water 60 flowing in the pipe 120. The control unit 600 adjusts the flow rate of the cooling water 60 so that the temperature of the heating cooling water is about 40 ~ 70 ℃.

 Then, the heating coolant supplied to the hose 300 is discharged to the hole 310 provided on the outer surface of the hose 300 (S70-1). As described above, the hose 300 is installed on the outer surface 20 of the concrete structure 10. Therefore, the heating coolant discharged from the hose hole 310 may naturally flow down along the outer surface 20. The outer surface 20 is covered by the curing cloth 200. Therefore, the curing cloth 200 absorbs a part of the heating water 61, and the outer surface 20 is heated by the heating coolant absorbed by the curing cloth 200 (S80-1). In addition, as described above, since the curing cloth 200 is covered by the insulating member 210, the outer surface 20 is efficiently heated while having a heat insulating effect by the insulating member 210. Therefore, the inside of the concrete structure 50 is cooled by the coolant 60 flowing inside the pipe 120, and the outer surface 20 is heated by the heating coolant discharged to the hose hole 310, thereby providing the concrete structure 10. The temperature difference between the inner 50 and the outer surface 20 of the can be reduced.

The heated cooling water discharged from the hose hole 310 is collected in the water recovery duct 400 and recovered to the main water tank 100 through the recovery pipe 130 (S90-1). And, this circulation is continued until the internal temperature of the concrete structure 10 is less than the set specific temperature. In addition, further comprising a recovery pump for recovering the heating cooling water to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting the position and the main water tank 100 where the flowing cooling coolant is collected. It is also configured to recover the heating cooling water to the main water tank (100).

In addition, when the internal temperature of the concrete structure 10 is less than the predetermined temperature (for example, about 50 ℃), the internal temperature of the concrete structure 10 is too low, the cooling water 60 is no longer supplied to the heating Since the external surface 20 cannot be heated. Therefore, when the internal temperature of the concrete structure 10 is below a predetermined temperature (for example, about 50 ° C.) (S100-1), the controller stops the operation of the first pump 110 to pipe 120 The cooling water 60 is blocked to supply (S110-1). Then, the control unit 600 operates the second pump 730 to supply the heating water 61 stored in the auxiliary water tank 700 to the supply pipe 710 (S120-1).

Then, the heating water 61 is supplied to the outer surface 20 of the concrete structure 10 through the supply pipe 710 (S130-1). Thus, by supplying the heating water 61 to the outer surface 20 of the concrete structure 10, the outer surface 20 of the concrete structure 10 is heated (S140-1).

In addition, the auxiliary water tank 700 is provided with a heating means 500, and heats the stored heating water 61 to a temperature of about 40 ~ 70 ℃. Thus, the heated water 61 stored in the auxiliary water tank 700 is supplied to the concrete structure outer surface 20 through the supply pipe 710 and the outer surface 20 of the concrete structure 10 by the heated water 61. Will be heated. The heated water 61 supplied to the outer surface 20 is absorbed by the curing cloth and flows down to collect in the water duct 400. Then, it is recovered to the main water tank 100 again through the recovery pipe 130 connected to the water recovery duct 400. In addition, to recover the heated water 61 to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting between the position where the heated water 61 flowed down and the main water tank 100. It may be configured to further include a recovery pump.

In addition, a connection pipe 740 is provided between the main water tank 100 and the sub water tank 700, and the cooling water 60 is supplied to the sub water tank 700 to the main water tank 100, and to the sub water tank 700. The heated water 61 heated by the installed heating means 500 is circulated while being supplied to the outside of the concrete structure 10 through the supply pipe 710. This circulation starts when the internal temperature of the concrete structure 10 becomes below a certain temperature and continues until curing ends. Finally, after curing of the concrete structure 10 is finished, the structure 10 is completed by grouting filling in the pipe 120.

FIG. 6 is a graph illustrating an external surface 20 temperature, an internal 50 temperature, and a temperature difference graph of the concrete structure 10 during curing time according to the conversion temperature difference reducing method according to the first embodiment of the present invention. As shown in FIG. 6, the time point at which curing is completed takes about 4 to 7 days. Compared with the graph shown in Figure 1c, it can be seen that the curing time is significantly reduced. In addition, when the reduction method according to the first embodiment of the present invention is carried out, the rising width of the inner 50 of the concrete structure 10 decreases, and the temperature of the outer surface 20 of the concrete structure 10 increases. do. Therefore, the temperature difference between the internal 50 temperature and the external surface 20 temperature of the concrete structure 10 is reduced. As shown in FIG. 6, it can be seen that the maximum value of the temperature difference (ΔT = T ₁ -T ₂ ) is also significantly reduced when compared with FIG. 1A.

< In the second embodiment  According Conversion  Configuration of temperature difference reducing device Reduction Method >

Hereinafter, the configuration of the conversion type temperature difference reducing apparatus according to the second embodiment will be described. First, Figure 7 shows a perspective view of a conversion type temperature difference reducing apparatus according to a second embodiment of the present invention. 8 is a plan view of the conversion type temperature difference reducing apparatus according to the second embodiment of the present invention.

As shown in FIG. 7 and FIG. 8, the conversion type temperature difference reducing apparatus according to the second embodiment, as in the first embodiment, the hose 300 installed on the upper surface of the concrete structure 20, the inside of the concrete structure 50. ) Pipe 120, the main water tank 100, the coolant 60 is stored, the first pump 110, the water recovery duct 400, the curing cloth 200, the insulating member 210, the recovery through Pipe 130, the auxiliary water tank 700, the heating water 61 is stored therein, the second pump 730, the supply pipe 710 for supplying the heating water 61, the main water tank 100 and the auxiliary water tank ( It includes a connection pipe 740, the third pump 750 and the control unit 600 for connecting the 700.

However, unlike the first embodiment, the conversion type temperature difference reducing device according to the second embodiment of the present invention further includes a conversion valve 720 between the supply pipe 710 and the end of the pipe 120 and the hose. Hereinafter, a description will be given of the conversion type temperature difference reducing apparatus according to the second embodiment centering on the difference from the first embodiment.

In the initial stage of curing (when the internal temperature of the concrete structure 10 is above a certain temperature), the control unit controls the conversion valve 720 to block the supply of the heating water 61 from the supply pipe 710 to the hose 300. Then, the cooling water 60 is supplied from the main water tank 100 to the pipe 120. Therefore, in the initial stage of curing, the control unit operates the first pump 110 to move the cooling water 60 from the main water tank 100 to the pipe 120, and the concrete by the cooling water 60 supplied to the pipe 120. The inside of the structure 10 is cooled, and at the same time the coolant 60 is heated and supplied to the hose 300 as the heating coolant. The heating coolant supplied to the hose 300 is discharged through the hose hole 310 to heat the outer surface 20 of the concrete structure, gathered into the water recovery duct 400, as in the first embodiment, and the recovery pipe 130. Through the main water tank 100 is recovered again. In addition, further comprising a recovery pump for recovering the heating cooling water to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting the position and the main water tank 100 where the flowing cooling coolant is collected. It may be configured to.

In the curing step (that is, when the internal temperature of the concrete structure 10 becomes below a specific temperature), the control unit controls the conversion valve 720 to supply the coolant 60 to the hose 300. And the heating water 61 is supplied to the hose 300 by the supply pipe 710. That is, when the internal temperature of the concrete structure 10 is below a certain temperature, the cooling water 60 supplied to the pipe 120 is no longer heated, so that the conversion valve 720 is operated to operate with the pipe 120. It blocks the circulation between the hose (300).

When opening between the supply pipe 710 and the hose 300 by the conversion valve 720, the heating water 61 stored in the auxiliary tank 700 is supplied to the hose 300 through the supply pipe 710. do. Accordingly, the heated water 61 supplied to the hose 300 is discharged to the hose hole 310, and the heated water 61 discharged to the hose hole 310 forms the outer surface 20 of the concrete structure 10. Heating. Then, the heating water 61 is collected in the water recovery duct 400, and is recovered to the main water tank 100 again through the recovery pipe 130. In addition, to recover the heated water 61 to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting between the position where the heated water 61 flowed down and the main water tank 100. It may be configured to further include a recovery pump. Then, the main water tank 100 and the auxiliary water tank 700 are connected by a connection pipe 740. The auxiliary water tank 700 is provided with a heating means 500 to heat the heating water 61 stored in the auxiliary water tank 700.

9 is a block diagram illustrating a signal flow of a controller according to a second embodiment of the present invention. As shown in FIG. 9, as in the first embodiment, the controller receives the internal temperature measured by the central temperature sensor provided in the concrete structure 10, and is provided on the surface portion of the concrete structure 10. The temperature difference is calculated in real time by receiving the measured surface temperature from the temperature sensor.

When the curing starts, the control unit operates the first pump 110 and supplies the cooling water 60 stored in the main water tank 100 to the pipe 120. And, if the internal temperature of the concrete structure 10 is below a specific temperature, the control unit operates the conversion valve 720 to cut off between the pipe 120 and the hose 300. Then, the supply pipe 710 and the hose 300 is opened. Therefore, the heated water 61 stored in the auxiliary water tank 700 is supplied to the hose 300 through the supply pipe 710. Then, the control unit controls the heating means 500, so that the heating water 61 stored in the auxiliary water tank 700 is about 40 ~ 80 ℃.

Hereinafter, a second embodiment of the method for reducing concrete temperature difference according to the present invention will be described. First, FIG. 10 is a flowchart illustrating a method for reducing the conversion type concrete temperature difference according to the second embodiment of the present invention. Rebars are assembled and formwork is installed. Then, the pipe 120 is installed in the formwork. In addition, temperature sensors 71 and 72 may be installed inside the formwork. Then, the concrete is poured into the formwork to form the concrete structure 10 (S10-2).

Then, one end of each of the pipes 120 is connected to the main water tank 100 in which the coolant 60 is stored, and the other end is connected to the hose 300. The hose 300 connected to the pipe 120 is installed on the outer surface 20 of the concrete structure 10 (S20-2). As described above, the end of the hose 300 is blocked, a plurality of holes 310 are formed on the outer surface.

As curing of the concrete structure 10 starts, the temperature difference between the interior 50 of the concrete structure and the external expression is generated by the heat of hydration of the concrete (S30-2). Temperature sensors 71 and 72 installed on the outer surface 20 and the inside 50 of the concrete structure 10 measure the temperature of the outer surface 20 and the inside 50. The controller 600 calculates the temperature difference in real time by the temperature of the outer surface 20 of the concrete structure 10 and the temperature of the inside 50 detected by the temperature sensors 71 and 72.

The controller 600 determines a supply speed of the cooling water 60 supplied to the pipe 120, that is, a flow rate of the cooling water 60 flowing in the pipe 120 based on the calculated temperature difference. As described above, the flow rate of the cooling water 60 flowing in the pipe 120 determines the temperature of the heating coolant supplied to the hose 300. Therefore, the flow rate of the cooling water 60 supplied to the pipe 120 based on the temperature difference calculated in real time may be adjusted in real time by the controller 600.

In the initial stage of curing, the control unit controls the conversion valve 720 to cut off between the supply pipe 710 and the hose 300 and open the pipe 120 and the hose 300. The controller 600 controls the first pump 110 to supply the coolant 60 into the pipe 120 at the set flow rate (S40-2). The coolant 60 supplied into the pipe 120 flows into the pipe 120 and is heated. That is, in the initial curing step, the cooling water 60 supplied to the pipe 120 has a temperature of about 0 ~ 30 ℃, the temperature of the interior 50 of the concrete structure 10 corresponds to about 70 ~ 100 ℃ The interior 50 of the concrete structure 10 is cooled by the cooling water 60 (S50-2). At the same time, the cooling water 60 supplied to the pipe 120 is heated. The heated cooling water 60 is supplied to the hose 300 as the heating coolant (S60-2). As described above, the temperature of the heating coolant supplied to the hose 300 is determined by the temperature of the interior 50 of the concrete structure 10 and the flow rate of the cooling water 60 flowing in the pipe 120. The control unit 600 adjusts the flow rate of the cooling water 60 so that the temperature of the heating cooling water is about 40 ~ 70 ℃.

 Then, the heating coolant supplied to the hose 300 is discharged to the hole 310 provided on the outer surface of the hose 300 (S70-2). As described above, the hose 300 is installed on the outer surface 20 of the concrete structure 10. Therefore, the heating coolant discharged from the hose hole 310 may flow down naturally. The outer surface 20 is covered by the curing cloth 200. Therefore, the curing cloth 200 absorbs a portion of the heating coolant, and the outer surface 20 is heated by the heating cooling water absorbed by the curing cloth 200 (S80-2).

In addition, as described above, since the curing cloth 200 is covered by the insulating member 210, the outer surface 20 is efficiently heated while having a heat insulating effect by the insulating member 210. Therefore, the inside of the concrete structure 50 is cooled by the coolant 60 flowing inside the pipe 120, and the outer surface 20 is heated by the heating coolant discharged to the hose hole 310, thereby providing the concrete structure 10. The temperature difference between the inner 50 and the outer surface 20 of the can be reduced.

The heated cooling water discharged from the hose hole 310 is collected in the water recovery duct 400 and then recovered to the main water tank 100 through the recovery pipe 130 (S90-2). In addition, further comprising a recovery pump for recovering the heating cooling water to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting the position and the main water tank 100 where the flowing cooling coolant is collected. It may be configured to. And, this circulation is continued until the internal temperature of the concrete structure 10 is less than the set specific temperature.

In addition, when the internal temperature of the concrete structure 10 is lower than a predetermined temperature (for example, about 50 ° C.) in the middle stage of curing, the internal temperature of the concrete structure 10 is too low, and no longer supplied cooling water ( Since the 60 is not heated, the outer surface 20 cannot be heated. Therefore, when the internal temperature of the concrete structure 10 is below a predetermined temperature (for example, about 50 ° C.) (S100-1), the controller stops the operation of the first pump 110 to pipe 120 The cooling water 60 is blocked to supply (S110-2). Then, the control unit operates the second pump 730 and simultaneously controls the conversion valve 720 to cut off between the pipe 120 and the hose 300, and open between the supply pipe 710 and the hose 300. do. Therefore, the heating water 61 stored in the auxiliary water tank 700 is supplied to the supply pipe 710 (S120-2).

Then, the heated water 61 is supplied to the hose 300 through the supply pipe 710, and the heated water 61 is discharged to the hose hole 310 (S130-2). Therefore, by supplying the heating water 61 to the outer surface 20 of the concrete structure 10, the outer surface 20 of the concrete structure 10 is heated (S140-2).

In addition, the auxiliary water tank 700 is provided with a heating means 500, and heats the stored heating water 61 to a temperature of about 40 ~ 70 ℃. Therefore, the heating water 61 stored in the auxiliary water tank 700 is supplied to the hose 300 through the supply pipe 710, and the heating water 61 is discharged into the hose hole 310 to be heated by the heating water 61. The outer surface 20 of the concrete structure 10 is to be heated. The heated water 61 supplied to the outer surface 20 is absorbed by the curing cloth and flows down to collect in the water duct 400. Then, it is recovered to the main water tank 100 again through the recovery pipe 130 connected to the water recovery duct 400. In addition, to recover the heated water 61 to the main water tank 100 through the recovery pipe 130 and the recovery pipe 130 connecting between the position where the heated water 61 flowed down and the main water tank 100. It may be configured to further include a recovery pump.

In addition, a connection pipe 740 is provided between the main water tank 100 and the sub water tank 700, and the cooling water 60 is supplied to the sub water tank 700 to the main water tank 100, and to the sub water tank 700. The heated water 61 heated by the installed heating means 500 is circulated while being supplied to the outside of the concrete structure 10 through the supply pipe 710. This circulation starts when the internal temperature of the concrete structure 10 is below a certain temperature and continues until the end of curing (S150-2). Finally, after curing of the concrete structure 10 is finished, grouting filling in the pipe 120 is completed to complete the structure.

1: ground
10: concrete structure
20: outer surface
30: Pipe of the invention
40: water
50: inside the concrete structure
60: cooling water
61: heated water
71: surface temperature sensor
72: center temperature sensor
100: main water tank
110: pump
120: pipe
130: collection pipe
200: Curing cloth
210: thermal insulation member
300: Lake
310: lake hole
400: water recovery duct
500: heating means
600: control unit
700: auxiliary tank
710: supply pipe
720: switching valve
730: the second pump
740: connecting pipe
750: third pump

Claims (22)

In assembling the reinforcing bars, installing the formwork to cast concrete into the formwork, and then to reduce the temperature difference generated in the concrete structure formed by the poured concrete,
A main water tank with cooling water stored therein;
The cooling water is installed in the formwork, embedded in the concrete structure by the pouring of the concrete and penetrates the concrete structure and is spaced apart from each other at a predetermined interval, the cooling water stored in the main water tank connected to the main water tank Is supplied to the inside, the internal temperature of the concrete structure is reduced, the cooling water supplied to the inside is heated to output the heating coolant;
It is connected to the output end of each of the pipes, is installed on the outer surface of the concrete structure, the heating coolant output from the pipe is supplied to the inside, the outer surface is provided with a plurality of holes to discharge the heating coolant to the hole hose;
An auxiliary water tank with heated water stored therein;
A supply pipe connected to the auxiliary water tank to supply the heated water to the external surface when the internal temperature of the concrete structure is lower than a predetermined temperature; And
And a controller for supplying the cooling water from the main water tank to the pipe when the internal temperature of the concrete structure is greater than or equal to the specific temperature, and for supplying the heating water to the supply pipe from the auxiliary water tank below the specific temperature. Conversion type concrete temperature difference reduction device using pipe cooling technology during concrete curing. The method of claim 1,
The output end of the supply pipe is provided between the pipe and the hose,
When the internal temperature of the concrete structure is below the specific temperature, the conversion concrete temperature difference further comprises a conversion valve configured to block the supply of the cooling water, and supply the heating water to the hose by the supply pipe Abatement device. The method of claim 2,
At least one hose is installed on the outer surface of the concrete structure, the heating coolant or the heating water discharged from the hole flows to the outer surface,
Or a recovery pipe connected to the water recovery duct installed on the side of the concrete structure and the water recovery duct to recover the heating coolant or the heating water to the water tank, or
Is formed in the corner portion in contact with the concrete structure and the ground, the cooling water flows down to the outer surface or the channel for collecting the heating water and the number of recovery is connected to the water channel to recover the heating cooling water or the heating water to the main water tank Further includes a tube, or
And a recovery pipe connecting the position where the heated water or the cooling water flows down and the main water tank, and a recovery pump for recovering the heating water or the heating coolant to the main water tank through the recovery pipe. Conversion type concrete temperature difference reduction device applying pipe cooling technology during concrete curing. The method of claim 3, wherein
A first pump provided between the main water tank and the pipe to supply the cooling water to the pipe; and
The second concrete pump is provided between the auxiliary water tank and the supply pipe to supply the heating water to the supply pipe; Concrete type concrete concrete temperature difference reduction device using the pipe cooling technology during curing. The method of claim 4, wherein
And a curing cloth installed on the outer surface to absorb the heating coolant or the heating water discharged from the hole and absorb the heated cooling water or the heated water to contact the outer surface. Convertible concrete temperature difference reduction device using municipal pipe cooling technology. The method of claim 5, wherein
Apparatus for reducing the concrete temperature difference applied to the pipe cooling technology during concrete curing, characterized in that it further comprises a thermal insulation member for curing the curing to absorb the heating cooling water or the heating water absorbed by the curing cloth. The method according to claim 6,
The thermal insulation member is a convertible concrete temperature difference reduction device applying the pipe cooling technology during concrete curing, characterized in that the vinyl canvas or bubble sheet. The method of claim 4, wherein
The auxiliary water tank further comprises a heating means for heating the heating water stored in the auxiliary water tank converting concrete concrete temperature difference reduction device applying the cooling technology, characterized in that the heating. The method of claim 8,
And a central temperature sensor provided on the outer surface to measure a temperature of the outer surface and a central temperature sensor provided inside the concrete structure to measure an internal temperature of the concrete structure.
The control unit is connected to the heating means, and supplies power to the heating means, and when the internal temperature measured by the central temperature sensor is less than the specific temperature is activated to the conversion valve is supplied to the hose from the pipe The conversion-type concrete temperature difference reduction device using the pipe cooling technology during concrete curing, characterized in that the heating cooling water is blocked, and the heating pipe is supplied to the hose from the supply pipe. The method of claim 9,
Converted concrete temperature difference reduction device applied to the pipe cooling technology during concrete curing, characterized in that it further comprises a connection pipe provided between the main tank and the auxiliary tank to supply the cooling water stored in the main tank to the auxiliary tank. The method of claim 9,
The control unit
By controlling the first pump to adjust the flow rate of the cooling water supplied to the pipe,
Converted concrete temperature difference reduction device applying the pipe cooling technology during the curing of the concrete, characterized in that for controlling the second pump to adjust the flow rate of the heating water supplied to the hose. The method of claim 11,
The control unit calculates the temperature difference between the outer surface and the inside of the concrete structure, when the temperature difference is more than a predetermined temperature difference, by operating the first pump to supply the cooling water to the pipe during concrete curing, characterized in that the pipe cooling technology Conversion type concrete temperature difference reduction device. Assembling reinforcing bars and formwork, installing at least one pipe inside the formwork, and installing the pipes through the concrete structure formed by pouring concrete into the formwork;
Installing at least one hose having a plurality of holes on the outer surface of the concrete structure, connecting each of the other end of the pipe with the hose, and each of the one end of the pipe is connected to the main tank for storing the cooling water therein, Installing an auxiliary tank for storing heated water therein and a supply pipe for supplying the heated water to an outer surface of the concrete structure;
Installing a water collecting duct on the side of the concrete structure or installing a water channel at a corner portion of the concrete structure and the ground contacting with the ground;
Generating a temperature difference between the inner surface of the concrete structure and the outer surface, and supplying the cooling water stored in the main water tank to the pipe by a first pump;
Cooling the inside of the concrete structure by the cooling water supplied to the pipe, and heating the cooling water to supply heating coolant to the hose;
The heating cooling water is supplied to the hose, the heating cooling water is discharged through the hole, and the outer surface is heated, and the heating cooling water is collected in the water channel or the water collecting duct, and then is returned to the main water tank through the collecting pipe. Recovering the heated cooling water that has been recovered or flowed down by the recovery pump installed in a recovery pipe to the main water tank; And
When the internal temperature of the concrete structure is less than the predetermined temperature, the control unit stops the operation of the first pump to cut off the supply of the cooling water supplied by the pipe, the first installed between the supply pipe and the auxiliary tank And operating the pump to supply the heated water to the outer surface of the concrete structure by the supply pipe. 2. The method of claim 13,
The supply pipe installation step,
Installing a conversion valve between the pipe and the hose, and connecting the conversion valve and the supply pipe,
The heating water is supplied to the outer surface of the concrete structure
When the internal temperature of the concrete structure is below the specific temperature, the control unit operates the conversion valve to cut off the supply of the cooling water supplied by the pipe, and supply the heating water to the hose by the supply pipe. Converted concrete temperature difference reduction curing method comprising the; further comprising. The method of claim 13,
The supply pipe installation step,
Further comprising the step of installing a curing cloth on the entire outer surface,
In the recovery step, the conversion type concrete temperature difference reduction curing method, characterized in that the curing cloth absorbs a part of the heated water discharged from the hole. The method of claim 15,
After the curing step installation step,
Converting concrete temperature difference reduction curing method further comprising the step of installing a heat insulating member on the curing cloth. The method of claim 13,
The control method further comprises the step of heating the heating water by supplying power to the heating means installed in the auxiliary water tank converted concrete temperature difference reduction curing method. The method of claim 17,
The controller
Adjust the flow rate of the cooling water supplied to the pipe,
Conversion-type concrete temperature difference reduction curing method, characterized in that for controlling the flow rate of the heating water supplied to the supply pipe. The method of claim 18,
By the external surface temperature and the internal temperature of the concrete structure measured by the surface temperature sensor installed on the outer surface and the central temperature sensor installed inside the concrete structure,
And converting, by the controller, the temperature difference between the outer surface and the inside, and operating the first pump when the temperature difference is greater than or equal to a preset temperature difference. The method of claim 13,
Before the heating water is supplied to the outer surface of the concrete structure,
And installing a connection pipe between the main tank and the auxiliary tank, and supplying the cooling water stored in the main tank to the auxiliary tank. 21. The method of claim 20,
After curing of the concrete structure is completed,
The concrete temperature difference reduction curing method further comprises the step of grouting in the pipe. The concrete structure cured by the concrete temperature difference reduction curing method of claim 13.

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