KR102069201B1 - concrete curing equipment with improved steam thermal efficiency for architecture and civil structure - Google Patents

Abstract

The present invention relates to equipment for curing a precast concrete member for a building and construction with increased steam heat preservation efficiency. According to the present invention, since a steam pipe is included in the upper and lower parts of a mold to cure a precast member (a girder, a pillar, a slab, and the like) for a building and construction, steam is applied to both upper and lower surfaces of concrete to increase curing (drying) efficiency. At this time, an insulation tent is installed (in winter) on an upper part to minimize a steam loss such that airtightness is maintained to prevent heat from going out so as to increase thermal efficiency. Moreover, while a strand of a concrete member is exposed to the outside through a gap between cut parts of the insulation tent, a magnet is disposed on the lower end of the cut part such that adjacent cut parts are attached to each other to prevent steam from going out by sealing.

Description

Concrete curing equipment with improved steam thermal efficiency for architecture and civil structure}

The present invention improves curing efficiency (drying) because steam pipes are provided on the upper and lower parts of the mold to cure precast members (girders, columns, slabs, etc.) for building and civil engineering structures, respectively. The present invention relates to a precast concrete member curing facility for construction and civil engineering, in which steam heat storage efficiency is improved.

In this case, in order to minimize the loss of steam (winter), the insulation tent may be covered with an upper portion to maintain airtightness to prevent heat from escaping.

In addition, the strand of the concrete member is exposed to the outside through the gap between the cut incision of the thermal insulation tent, the magnet is provided at the bottom of the incision, the adjacent incision is attached to each other, so that the steam does not leak out due to the sealing.

In general, PC (Precast concrete) structure is subjected to curing process after placing concrete in a prefabricated mold.

PC structures manufactured as such are mainly used in buildings due to fire resistance, durability, shock resistance and economic effects.

In the related art, as the curing method of the PC structure as described above, a natural curing method such as the sun or the wind is used without an additional artificial facility.

However, in the natural curing method, there is a problem of cracking on the exterior of the concrete structure due to rapid drying due to the rapid temperature difference with the outside after the concrete is placed.

Accordingly, Republic of Korea Patent Publication No. 10-1938157 (Registration Date: 2019.10.08) relates to the concrete block curing room, the trays loaded with concrete blocks sequentially provided in the tray support portion provided to protrude on both sides of the bottom of the curing room There is a prior document named Concrete Block Curing Room which allows it to be settled and then quickly cured to have a uniform strength by steam supplied through the steam supply.

However, the above-mentioned prior document has a steam supply only at the bottom of the curing chamber, so the concrete block does not receive steam heat evenly in the upper and lower sides, and the curing efficiency is lowered. There was a problem that fell very much.

In order to achieve the above object, the present invention is to provide a steam pipe is provided in the upper and lower parts of the mold for curing the construction, civil structure precast member, respectively, so that the concrete is applied to the upper and lower steam. .

At this time, in order to minimize the loss of steam (winter), the insulation tent is covered with an upper part to provide airtightness to prevent heat from escaping.

In addition, the strand of the concrete member is exposed to the outside through the gap between the cut incision of the thermal insulation tent, the purpose is to provide that the magnet is provided at the bottom of the cut.

In order to achieve the above object, the present invention is located on the rail (R) formed on the ground mold 100 is cured concrete (C) protrudes on one side; The main steam pipe 210 is formed on one side of the mold 100 and receives steam from a separate steam supply source, and is branched from the main steam pipe 210 to penetrate one side of the rail R to mold 100. A lower part pipe 220 is formed to supply hot air from the lower part, and branched from the main steam pipe 210 to surround the upper part of the mold 100 in an arc shape to supply hot air from the upper part of the mold 100 ( A steam unit 200 in which 230 is formed; To the thermal insulation tent 300 is covered on the steam unit 200, the upper branch pipe 230; It is made up.

At this time, steam is opened and closed by the valve (V) of the lower part pipe 220 and the upper branch pipe 230 branching from the main steam pipe 210.

In addition, the side end 310 of the insulated wire (i) of the insulation tent 300 is formed in a plurality of cut shape.

Therefore, the present invention is provided with steam pipes on the upper and lower molds respectively for curing precast members (girder, column, slab, etc.) for construction and civil construction, so that the concrete is steamed from both the upper and lower sides, curing efficiency (drying). This improved steam heat preservation efficiency is improved.

At this time, in order to minimize the loss of steam (winter), the thermal insulation film is covered with an upper portion to maintain airtightness so that heat does not escape, thereby improving thermal efficiency.

In addition, the strand of the concrete member is exposed to the outside through the cut gap of the thermal insulation tent, but the steam does not leak to the outside has the effect of improving the curing efficiency.

1 to 3 is an exemplary view showing the overall appearance of the precast concrete member curing facility for construction, civil structural improvement of steam heat storage efficiency according to the present invention,
Figure 4 is an illustration showing that the end of the insulating tent cut in accordance with the present invention,
5 is an exemplary view showing that a viewing window is formed on the thermal insulation tent according to the present invention;
6 is an exemplary view showing that the fixing part is provided in the mold according to the present invention.

First, as shown in FIGS. 1 to 6, the present invention includes a mold 100, a steam unit 200, and a thermal insulation membrane 300.

Thus, the present invention, but there are a variety of PC members such as PC slab, PC girder, PC pillar, PC wall will be described with reference to PC slab in Figures 1 to 6.

Thus, as shown in Figures 1 to 3, the mold 100 is located on the rail (R) formed in the ground, but the concrete (C) is protruded to one side of the strand (i) is cured girder, slab, Mass production of concrete products such as columns.

In addition, the steam unit 200 is formed on one side of the mold 100, the main steam pipe 210 is supplied with steam from a separate steam supply source is formed.

At this time, branched from the main steam pipe (210) through the rail (R) in a zigzag to form a lower portion of the tube (220) for supplying heat from the bottom of the mold 100 to form the curing of the concrete (C).

 Branched from the main steam pipe 210 is formed in the upper branch pipe 230 for supplying the steam toward the concrete (C) from the mold upper side surrounding the mold 100 in an arc shape.

Thus, the lower part engine 220 and the upper branch pipe 230 branching from the main steam pipe 210 are opened and closed by a valve (V).

In addition, the thermal insulation tent 300 is covered on the upper branch pipe 230 of the steam unit 200.

At this time, the reinforcing steel wire embedded inside the concrete is projected out of the insulation tent to prevent the steam is lost to the outside to lower the thermal efficiency.

At this time, the lower part pipe 220 and the upper branch pipe 230 is a steam discharge hole (not shown) is formed to apply the indirect and direct heat of steam to the concrete (C) by discharging the steam.

Thus, both sides of the insulated wire (i) of the insulation tent 300 is formed in a plurality of cut shape.

In more detail, the side end 310 is formed with a plurality of incisions 311 are cut into a plurality, the strand (i) is exposed between each of the incisions 310, the heat of the steam portion in the thermal insulation membrane 300 By softening, the curing of the concrete (C) is facilitated.

At this time, as shown in Figure 4, the lower side of each of the cut-out portion 311 of the side end 310 is provided with a magnet 312 so that the mutually opposite cut-outs 311 are attached to each other to minimize heat loss will be.

That is, the lower ends of each of the adjacent cutouts 311 are attached to each other by the magnets 312, so that the cutouts 311 are in a state in which only the upper part where the strands i protrude is opened to the minimum, and the lower end is the magnets 312. In a closed state by), the heat inside the thermal insulation membrane 300 is minimized to escape from the outside as well as the incision due to the wind due to the weight of the magnet 312 is not fluttered.

In addition, gasket soles 313 are formed at both ends and the lower ends of the cutouts 311 to minimize the escape of heat into the gaps between the cutouts 311 and below the cutouts.

At this time, the strand (i) is a general strand that is provided inside to strengthen the durability of the concrete product.

In addition, as shown in FIG. 5, a plurality of viewing windows 320 are formed at an upper side of the insulating tent 300 so that an operator may check the state of the concrete (C).

In addition, as shown in FIG. 6, the shielding end 330 of the thermal insulation membrane 300 has a fixing part 110 at one side in the longitudinal direction of the mold 100 in order to prevent the steam from leaking out of the mold 100. Is formed.

Thus, the fixing part 110 is provided with a pair of guide portion 111 on one side of the mold 100, the guide groove (H) is formed on the surface of each guide portion facing each other, the guide groove (H) The feed roller 112 is transported along the pressing to prevent the steam from escaping to the outside by pressing the shielding end of the thermal insulation tent 300 toward the mold 100.

More specifically, the feed roller 112 is formed on both sides of the shaft 113, the end of the shaft 113 is provided with a bearing conveying body 114 is transported along the guide groove (H), the bearing is Elastic spring (S) is provided between the body 114 and the guide groove (H), the feed roller 112 is always based on the state pressed toward the mold (100) side.

At this time, the feed roller 114 by the bearing carrier 114 is in a state capable of idling.

Accordingly, the upper and lower portions of the bearing transfer member 114 are provided with anti-separation protrusions, and inside the guide groove H, an anti-seizure groove having a shape corresponding to the anti-seizure protrusion is provided, so that the bearing carrier is a guide groove (H). Don't leave

At this time, the feed roller 114 is made of a urethane material.

Thus, the fixing part 110 is provided on both sides of the mold 100 so as not to lift the shielding end 330 of the thermal insulation membrane 300.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes are intended to fall within the scope of the claims.

100 ... mold 110 ... fixing part
111 ... guide part 112 ... feed roller
113 ... shaft 114 ... bearing carrier
200 ... steam 210 ... main steam pipe
220 ... lower subsystem 230 ... upper branch
300 ... thermal insulation tent 310 ... side end
311 ... incision 312 ... magnet
313 ... gasketing brush 320 ... viewing window
330 ...

Claims (3)

Located on the rail (R) formed in the ground mold 100 is cured concrete (C) protruding on the one side (i); The main steam pipe 210 is formed on one side of the mold 100 and receives steam from a separate steam supply source. The main steam pipe 210 is branched from the main steam pipe 210 and penetrates one side of the rail R to mold 100. An upper branch pipe 220 for supplying heat from the lower part is formed, and branched from the main steam pipe 210 to surround the upper part of the mold 100 in an arc shape to supply the hot air from the upper part of the mold 100 ( A steam unit 200 in which 230 is formed; To the thermal insulation tent 300 is covered on the steam unit 200, the upper branch pipe 230; Made up,
The lower portion of the branch pipe 220 and the upper branch pipe 230 branching from the main steam pipe 210 is opened and closed by the valve (V),
Side end 310 of the insulation line (i) of the insulation tent 300 is formed in a plurality of cut shape,
Magnets 312 are provided at both sides of the lower ends of the cutouts 311 of the side ends 310 so that the cutouts 311 facing each other are attached to each other,
Gasket soles 313 are formed at both ends and the lower ends of the cutouts 311 to prevent heat from escaping between the cutouts 311 and the gaps below the cutouts.
A plurality of see-through windows 320 are formed on the thermal insulation tent 300 so that the worker can check the state of the concrete (C),
In order to prevent steam from leaking from the shielding end 330 of the thermal insulation membrane 300 in the mold 100, a fixing part 110 is formed at one side in the longitudinal direction of the mold 100, and the fixing part 110 is formed. The mold 100 is provided with a pair of guide portions 111 on one side, each guide portion is formed with a guide groove (H) formed on the surface facing each other, the feed roller 112 is transported along the guide groove (H) ) Is provided to press the shielding end of the thermal insulation membrane 300 in the mold 100 to prevent the steam from escaping to the outside, the feed roller 112 is formed on both sides of the shaft 113, the shaft ( The end of the 113 is provided with a bearing conveying body 114 is transferred along the guide groove (H), but the elastic spring (S) is provided between the bearing conveying body 114 and the guide groove (H) feed roller 112 ) Is always on the basis of the state pressed toward the mold 100, the transfer roll by the bearing carrier (114) The roller 112 is in a state capable of idling, and the transfer roller 112 is a concrete curing facility with improved heat preservation efficiency, characterized in that made of urethane material. delete delete

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