KR101534674B1 - Apparatus and method for curing concrete using a vacuum radiating unit - Google Patents

Abstract

The present invention relates to a concrete curing apparatus and a concrete curing method using a vacuum heat dissipating unit capable of rapidly curing concrete in a cold region or in winter and minimizing cracking during curing of the concrete.
To this end, the present invention relates to a mold for forming an internal space into which a concrete mortar for forming a concrete structure is injected; And a vacuum heat dissipation unit disposed adjacent to a reinforcing bar for reinforcing the strength of the concrete structure on the inner space of the concrete mold and heating the concrete mortar, wherein the vacuum heat dissipation unit includes a heat transfer pipe, And a heater for heating a working fluid present in the heat transfer pipe, wherein the working fluid includes a powder having an infrared ray emitting characteristic and a medium vaporized by the heat of the heater Provides concrete curing equipment and concrete curing methods

Description

Technical Field [0001] The present invention relates to a concrete curing apparatus using a vacuum heat-dissipating unit and a concrete curing method using the vacuum heat-

The present invention relates to a concrete curing apparatus and a curing method, and more particularly, to a concrete curing apparatus using a vacuum heat dissipating unit capable of rapidly curing concrete in a cold region or winter season and minimizing cracking during curing of the concrete Device and concrete curing method.

Concrete cures a concrete mixture of cement, sand, gravel and water properly and is used as an important material in civil engineering or building structures to withstand natural winds such as water, fire, and earthquakes.

The concrete is produced in a batch plant and transported to a concrete conveying car called a concrete mixer, and then is poured and cured in a concrete structure.

The concrete is affected by environmental conditions such as temperature and humidity during the curing process, and the curing process of the concrete influences the quality of the concrete structure after the construction.

For example, when the construction is carried out in summer or winter, the strength of the concrete structure may be lowered due to unstable temperature and humidity conditions, and cracking may occur.

Therefore, curing method and curing period of concrete should take into consideration outside temperature, composition, type and size of the structure in addition to general concrete standard.

In particular, in the cold region, since the outside temperature is low, the time required for curing the concrete is prolonged, the concrete is heated. In order to prevent cracking during the curing process of the concrete, the inside of the concrete must be heated to have a uniform temperature do.

The object of the present invention is to provide a concrete curing apparatus and concrete curing method using a vacuum heat dissipating unit capable of rapidly curing concrete in a cold region or winter season and minimizing cracking during curing of the concrete .

According to an aspect of the present invention, there is provided a concrete structure for forming a concrete structure, And a vacuum heat dissipation unit disposed adjacent to a reinforcing bar for reinforcing the strength of the concrete structure on the inner space of the concrete mold and heating the concrete mortar, wherein the vacuum heat dissipation unit includes a heat transfer pipe, And a heater for heating a working fluid present in the heat transfer pipe, wherein the working fluid includes a powder having an infrared ray emitting characteristic and a medium vaporized by the heat of the heater Provides a concrete curing device.

The heater may include a heating case surrounding at least a part of the heat transfer pipe, and a heating element inserted into the heating case.

The concrete curing apparatus may further include a gap holding member for maintaining a gap between the rebar and the heat transfer pipe at a constant level and for transmitting heat generated from the heat transfer pipe to the concrete mortar.

According to another aspect of the present invention, there is provided a method of reinforcing a concrete structure, comprising the steps of: installing a rebar to reinforce strength of a concrete structure; Installing a vacuum heat-dissipating unit at least partially disposed adjacent to the reinforcing bar; Providing a mold for providing an internal space into which concrete mortar for forming the concrete structure is injected; Injecting a concrete mortar into the inner space of the mold; And a curing step of curing the concrete mortar while heating the inside of the concrete mortar by operating the vacuum heat dissipating unit. The present invention also provides a method of curing a concrete using the vacuum heat dissipating unit.

The concrete curing method may further include the step of maintaining a gap between the reinforcing steel bar and the vacuum heat-dissipating unit at a constant level and providing a gap holding member for transferring the heat generated in the vacuum heat-dissipating unit to the concrete mortar have.

The medium present in the heat transfer pipe provided in the vacuum heat dissipation unit is vaporized by the heat of the heater provided in the vacuum heat dissipation unit and simultaneously transfers heat while moving, The powder having the discharge characteristic can transmit heat to the concrete mortar rapidly while transferring heat while emitting infrared rays.

The effect of the concrete curing apparatus and the curing method using the vacuum heat-dissipating unit according to the present invention will be described as follows.

First, a vacuum heat-dissipating unit having a heat transfer pipe having a working fluid including a powder having an infrared ray emitting characteristic and a medium vaporized by heat is installed in a concrete mortar to maintain a constant temperature of the inside of the concrete mortar in a short period of time So that it is possible to reduce the curing period of the concrete and to prevent cracks from being generated in the concrete.

Secondly, the gap between the reinforcing bars installed in the concrete structure and the heat transfer pipe is kept constant, and at the same time, the gap holding member for transferring the heat generated in the heat transfer pipe to the concrete mortar is provided to increase the strength of the concrete structure It is possible to maintain the internal temperature of the concrete mortar more efficiently and at the same time.

FIG. 1 is a cross-sectional view showing a state where concrete is cured according to a concrete curing apparatus according to the present invention.
2 is a cross-sectional view showing a section II of Fig.
3 is a sectional view of a vacuum heat-dissipating unit provided in the concrete curing apparatus of FIG.
4 is a flowchart sequentially illustrating concrete curing methods according to the present invention.
5 is a cross-sectional view showing another embodiment of the concrete curing device according to the present invention.

Hereinafter, embodiments of a concrete curing apparatus and concrete curing method using the vacuum heat dissipating unit according to the present invention will be described with reference to the accompanying drawings.

1 to 3, an embodiment of a concrete curing device according to the present invention will be described below.

The concrete curing apparatus according to the present embodiment includes a mold 10 for forming an internal space into which concrete mortar 1 for forming a concrete structure is injected and a concrete mortar 10 installed on the inner space of the former 10, 1 for heating the vacuum heat-dissipating unit.

The concrete structure cured by the concrete curing device according to the present embodiment corresponds to a vertical member, and the concrete structure is installed on the upper portion of the base member 3.

A reinforcing bar 20 for reinforcing the strength of the concrete structure is installed on the inner space of the mold 10 and the reinforcing bar 20 is disposed adjacent to the heat transfer pipe of the vacuum heat-dissipating unit.

Further, the reinforcing bar 20 and the heat transfer pipe are fastened by a separate fastening member, for example, a wire, so that they are stably fixed in the mold 10. [

The vacuum heat dissipation unit 100 includes a heat transfer pipe and a heater 160 for heating a working fluid 170 existing in the heat transfer pipe.

The inside of the heat transfer pipe is maintained in a vacuum state. A working fluid 170 containing a medium vaporized by the heat of the heater 160 and powder having an infrared ray emitting property is built in the heat transfer pipe.

The medium occupies 15% to 30% of the internal space of the heat transfer pipe based on the volume of the heat transfer pipe, and the powder occupies 0.5% to 2% of the internal space.

Examples of the medium include methyl alcohol, ethyl alcohol, ammonia, and methyl chloroform. As the powder, silicate mineral powder, jade powder, carbon powder, etc. may be used. Here, the powder is irrelevant to any minerals that emit infrared light when heated.

Particularly, since the inside of the heat transfer pipe is in a vacuum state, for example, an internal pressure of 0.001 to 0.0001 mmHg, the movement of the vaporized medium inside the heat transfer pipe proceeds at a very high speed.

In addition, since the inside of the heat transfer pipe maintains a vacuum state, heat transfer due to radiant heat of the infrared ray emitted from the powder and the vaporized medium becomes large.

The heat transfer pipe includes a pipe body 130, a first compression stopper 120 for firstly sealing the pipe body 130 at one end of the pipe body 130, And a first pipe outer cap 110 sealing the one end of the pipe main body 130 while being disposed at an upper portion of the pipe main body 130.

The heat transfer pipe includes a second compression stopper 150 for firstly sealing the pipe main body 130 at the other end of the pipe main body 130 and a second compression stopper 150 disposed below the second compression stopper 150, And a second pipe outer cap 140 for sealing the other end of the main body 130.

A first inner protruding protrusion 131 protruding from the inner surface of the upper end region of the pipe body 130 for pressing a part of the first crimping plug 120 while corresponding to the first crimping plug 120 , And a second inner protruding protrusion 133 protruding from the inner surface of the lower end region of the pipe body 130 for pressing a part of the second crimping plug 150 while corresponding to the second crimping plug 150 .

A first pipe thread 132 for coupling with the first compression stopper 120 is formed on the inner surface of the upper end region of the pipe main body 130. A lower end end region of the pipe main body 130, And a second pipe thread 134 for coupling with the second compression stopper 150 is formed on the inner side surface.

The first crimping plug 120 includes a first plug crimping portion 121 corresponding to the first inner protrusion 131 and a second crimping portion 121 extending from the first plug crimping portion 121, And a first plug coupling portion 123 coupled with the first plug coupling portion 123.

The first inner protruding protrusion 131 is made of stainless steel and the first crimping plug 120, i.e., the first plug crimping portion 121 is made of copper.

Therefore, when the first compression stopper 120 is assembled and inserted into the pipe body 130, the first inner protrusion protrusion 131 digs the outer surface of the first stopper compression portion 121 The first stopper portion 121 is compressed to primarily seal the upper region of the inner space of the pipe body 130.

The first closure part 123 is provided with a jig (not shown) for rotating the first closure cap 120 so that the first closure cap 120 is coupled to the inside of the pipe body 130, The first jiggut groove 123a is formed.

The first pipe outer cap 110 includes a first plug insertion portion 111 inserted into an upper end of the pipe body 130 and a second plug insertion portion 111 inserted into an upper end of the pipe main body 130, (113).

The first plug inserting part 111 and the first plug inserting part 113 are stepped so that the upper end of the pipe body 130 is inserted into the first plug inserting part 111 and the first plug- (113).

Here, the upper end of the pipe body 130 and the first pipe outer stopper 110 are welded in the first welding area A.

The second pressing part 150 includes a second sealing part 151 and a second sealing part 153. The second sealing part 153 includes a second sealing part 153a, Respectively.

The second pipe outer cap 140 includes a second plug insertion portion 141 and a second plug exposing portion 143. The second pipe outer cap 140 includes a second welding region B, Is welded to the lower end of the pipe body.

Since the second compression stopper 150 and the second pipe outer stopper 140 have substantially the same structure as the first compression stopper 120 and the first pipe outer stopper 110, A detailed description thereof will be omitted.

The heater 160 includes a heating case 161 surrounding at least a portion of the heat transfer pipe and a heating element 165 inserted into the heating case 161.

As the heating element 165, a ceramic temperature (PCT: Positive Temperature Coefficient) heater is used. When the temperature of the heating element 165 is low, high heat is generated, and when the temperature is high, the heat generation amount is repeatedly decreased.

The heating case 161 is buried in the concrete mortar 1 and the heating element 165 is buried in the heating case 161.

In addition, a separate power supply connection line (not shown) is installed to connect the heating element 165 to an external power supply source. Of course, after the curing of the concrete is terminated, the exposed region of the concrete structure may be cut off and removed.

As a result, the vacuum heat dissipating unit 100 having the heat transfer pipe with the working fluid 170 containing the powder having the infrared ray emitting characteristic and the medium vaporized by the heat is installed inside the concrete mortar 1, 1) can be kept constant within a short period of time, thereby reducing the curing period of the concrete and preventing cracks from occurring in the concrete.

In addition, since the heat transfer pipe is made of steel, the strength of the concrete structure can be further reinforced.

The present invention is not limited to the above-described embodiment, and the concrete curing apparatus may further include a gap holding member (not shown) for keeping a constant distance between the reinforcing bar 20 and the heat transfer pipe.

The cavity holding member is formed with a receiving groove for receiving the reinforcing bar 20 and at least a part of the heat transfer pipe. Specifically, at least a portion of the outer surface of the reinforcing steel bar and the outer surface of the heat transfer pipe are accommodated in the receiving groove.

Also, the gap holding member may be made of a metal material to transmit heat generated from the heat transfer pipe to the concrete mortar 1 at the same time.

Further, the gap holding member is made of a metal material, so that the strength of the concrete structure can be additionally reinforced.

1 to 4, a concrete curing method according to the present invention will be described as follows.

First, the operator installs a reinforcing bar 20 to reinforce the strength of the concrete structure (S10).

Next, the operator installs the vacuum heat-dissipating unit 100 at least partially disposed adjacent to the reinforcing bar 20 (S20). Of course, the reinforcing bar 20 may be installed after the vacuum heat-dissipating unit 100 is installed first.

Next, the operator installs the formwork 10 to provide the internal space into which the concrete mortar 1 for forming the concrete structure is injected. (S30)

Next, the operator injects the concrete mortar 1 into the internal space of the mold 10 (S40).

Next, the operator operates the vacuum heat-dissipating unit 100 to heat the interior of the concrete mortar 1 to cure the concrete mortar 1 (S50, S60).

In the step of curing the concrete mortar, the medium present in the heat transfer pipe provided in the vacuum heat dissipation unit 100 is vaporized by the heat of the heater 160 provided in the vacuum heat dissipation unit, At the same time, the powder having the infrared ray emission characteristic existing inside the heat transfer pipe can transmit heat to the concrete mortar 1 while transferring heat while emitting infrared rays.

In addition, it is necessary to sufficiently supply the water required for curing the concrete.

It is needless to say that the present invention is not limited to the above-described embodiments. The concrete curing method may be performed by maintaining the interval between the reinforcing bar 20 and the vacuum heat-dissipating unit 100 constant, And installing spacing members for transferring the generated heat to the concrete mortar 1.

5, another embodiment of the concrete curing apparatus according to the present invention will be described.

The concrete curing apparatus according to the present embodiment is applied to a horizontally cured concrete structure.

The concrete curing apparatus comprises a mold 10 for forming an internal space into which a concrete mortar 1 for forming a concrete structure is injected in an upper portion of a base member 3, And a vacuum heat dissipation unit 200 for heating the concrete mortar 1.

The concrete curing apparatus according to the present embodiment is similar to the concrete curing apparatus according to the embodiment described above. However, the vacuum heat-dissipating unit 200, that is, the heat-transfer pipe and the heater 260 provided in the concrete curing apparatus according to the present embodiment is different from the above-described embodiment in that the inside of the mold 10 has a predetermined angle For example, 2 ° to 5 °.

This is because the medium in the working fluid existing inside the pipe body 230 of the vacuum heat dissipating unit is vaporized and moves upward.

The detailed structure of the heat transfer pipe and the heater 260 is substantially the same as that of the heat transfer pipe and the heater of the embodiment described above, and thus a detailed description thereof will be omitted.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention as claimed in the claims. And such variations are within the scope of the present invention.

1: Concrete mortar 10: Formwork
20: reinforcing steel 100,200: vacuum heat-dissipating unit
110: first pipe outer cap 120: first pressure cap
130, 230: Pipe body 140: First pipe outer cap
150: second crimping plug 160, 260: heater
161: Heating case 165: Heating element
170: working fluid

Claims (6)

A form for forming an internal space into which concrete mortar for forming a concrete structure is injected; And,
At least a portion of which is disposed adjacent to a reinforcing bar for reinforcing the strength of the concrete structure on an inner space of the formwork and for heating the concrete mortar,
Wherein the vacuum heat dissipating unit includes a heat transfer pipe and a heater for heating a working fluid existing in the heat transfer pipe,
Wherein the working fluid comprises a powder having an infrared radiation characteristic and a medium vaporized by heat of the heater,
Wherein the heater includes a heating case surrounding at least a part of the heat transfer pipe and a heating element inserted into the heating case. delete The method according to claim 1,
Further comprising a gap holding member for maintaining a gap between the reinforcing bar and the heat transfer pipe at a constant level and for transmitting heat generated from the heat transfer pipe to the concrete mortar. . In the method of curing concrete,
Installing reinforcing bars to reinforce the strength of the concrete structure;
Installing a vacuum heat-dissipating unit at least partially disposed adjacent to the reinforcing bar;
Providing a mold for providing an internal space into which concrete mortar for forming the concrete structure is injected;
Injecting a concrete mortar into the inner space of the mold;
A curing step of curing the concrete mortar while heating the inside of the concrete mortar by operating the vacuum heat dissipating unit; And,
And maintaining a gap between the reinforcing steel bar and the vacuum heat-dissipating unit constant and providing a gap holding member for transmitting heat generated in the vacuum heat-dissipating unit to the concrete mortar. Concrete curing method using. delete 5. The method of claim 4,
The medium present in the heat transfer pipe provided in the vacuum heat dissipation unit is vaporized by the heat of the heater provided in the vacuum heat dissipation unit and simultaneously transfers heat while moving, Wherein the powder having discharge characteristics rapidly transfers heat to the concrete mortar while transferring heat while emitting infrared rays.

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