KR102620286B1 - Rapid curing formwork system - Google Patents

Abstract

The present invention relates to a rapid heat curing formwork system, and is a formwork structure including a metal plate with one side facing the concrete pouring area and at least one first frame portion provided in a rectangular frame shape that is coupled to the other side of the plate and supports the plate. At least one heating plate that is attached to the other surface area of the plate section divided by the first frame section and heats the plate section by supplying electric signals, a temperature sensor that senses the temperature of the formwork structure, and a smoke plate according to the temperature sensed from the temperature sensor. It includes a control unit that controls the supply of electrical signals to.

Description

Rapid heat curing formwork system {RAPID CURING FORMWORK SYSTEM}

The present invention relates to a rapid heat curing formwork system for the production of concrete structures.

Concrete is a construction material that can produce various structures by pouring into molds made in various shapes and curing to cause a hydration reaction.

During the curing of concrete, if the temperature drops below a certain level, the hydration reaction does not occur smoothly, which increases the time required for hardening. As the entire construction period using the concrete structure is delayed, the appropriateness of the concrete curing process is increased. Maintaining temperature is a top priority.

Temperature control in the existing concrete curing process was achieved through steam generated by burning fossil fuels, but the use of fossil fuels can lead to fire accidents along with environmental problems that have recently emerged, so temperature management without the use of fossil fuels Technology has been required.

In order to solve this problem, in Republic of Korea Patent Publication No. 10-1911208 (Application date: 2018.03.30., Announcement date: 2018.12.28., hereinafter referred to as 'prior art'), a high-temperature fluid circulated through a flow path is used. Alternatively, a technology has been disclosed to manage the temperature during the curing process by transferring the heat generated from the chemical reaction of metal powder to the concrete poured inside the form through a heat transfer area located locally in each form.

However, since the prior art provides heat to the concrete poured into the form through heat generated through circulation of fluid or chemical reaction of metal powder, it is difficult to control and maintain the temperature immediately, and it is still necessary to input additional materials for heat generation. It is required, and there was a problem in that efficient temperature management was difficult because it was only delivered locally to some pouring areas of the concrete poured into the formwork.

In order to solve the above-mentioned problems, the purpose of the present invention is to provide a rapid heat curing formwork system that is capable of controlling the temperature of a large area of poured concrete and has increased thermal efficiency.

The rapid heat duplex formwork system according to an embodiment of the present invention includes a metal plate with one side facing the concrete pouring area, and at least one first frame provided in a rectangular frame shape that is coupled to the other side of the plate and supports the plate. formwork structure containing parts; At least one heating plate attached to the other surface area of the plate portion divided by the first frame portion and heating the plate portion by supplying an electric signal; A temperature sensor that senses the temperature of the formwork structure; And a control unit that controls the supply of an electric signal to the fume plate according to the temperature sensed from the temperature sensor, wherein the control unit determines the temperature of the form structure confirmed through the temperature sensor at a preset target temperature for each time. It is characterized by controlling the heat generation of the fuming plate so as to reach the value.

Here, the form structure interconnects a portion of the other surface area of the plate section partitioned by the first frame section and the inner opposing surface of the first frame section, and one area opposite the area to which the fume board is bonded is deleted. It is characterized in that it further includes at least one second frame portion provided in a shape.

And, the heating plate is attached to the other surface area of the plate portion divided by the deleted area of the first frame portion and the second frame portion, and includes a heating portion that heats the plate portion by an electric signal. an electrode portion disposed at both ends of the heating portion and including first and second electrode portions electrically connected to the heating portion, and transmitting an electrical signal supplied from the control unit to the heating portion; and an insulating part attached to an area of the other side of the plate adjacent to the electrode part and provided with an epoxy film, wherein the heating part is connected to the plate by a silicone adhesive linearly applied to the center area of the adhesive surface. It is characterized by being adhered to the other surface.

In addition, the control unit includes a confirmation unit connected to the temperature sensor to check the temperature of the formwork structure; a control unit that generates an electrical signal to control heat generation of the heating unit according to the temperature of the form structure confirmed by the confirmation unit and a preset target temperature value for each time; and a conductor portion connected to the control unit and a branch portion branched from the conductor portion and connected to the electrode portion, wherein the electrical signal generated from the control portion is individually transmitted to the first electrode portion and the second electrode portion of each electrode portion. It is characterized in that it includes a pair of connection parts for supplying.

At this time, the first frame portion has a through hole formed through which the conductive wire portion passes and is mounted so that each conductive portion of the pair of connecting portions is positioned adjacent to the first and second electrode portions of the smoke plate bonded to the plate portion. It is characterized by

In addition, the heating plate further includes an insulating portion provided in the form of a sheet that surrounds and adheres to the outer surface of the heating portion.

In addition, the heating plate may further include a film-shaped cover portion that is adhered to and surrounds the outer surface of the insulating portion and is made of a material harder than the insulating portion.

The rapid heat curing formwork system according to the present invention connects and supports the plate portion and the first frame portion provided in a rectangular frame shape in the vertical direction by removing the central area of the second frame portion facing the adhesive surface to which the heating plate is bonded, thereby increasing the support area. Compared to this, the applicable area of the heating plate has been increased, which has the effect of enabling rapid heat curing of concrete over a large area.

In addition, the rapid heat curing formwork system according to the present invention is provided in a form in which an insulating part and a cover part are stacked in the opposite direction of the adhesive surface of the heating part, thereby minimizing heat emission to the outside rather than the form structure, thereby increasing heating efficiency. It has the effect of preventing damage to the heating part due to external shock.

Figure 1 schematically shows the configuration of a rapid heat curing formwork system according to a preferred embodiment of the present invention.
Figure 2 shows the shape of the formwork structure in the rapid heat curing formwork system according to a preferred embodiment of the present invention.
Figure 3 shows the shape of the heating plate in the rapid heat curing formwork system according to a preferred embodiment of the present invention.
Figure 4 shows an example of temperature management of the formwork structure by the control unit in the rapid heat curing formwork system according to a preferred embodiment of the present invention.

Hereinafter, a preferred embodiment of the rapid heat curing formwork system of the present invention will be described in detail with reference to the attached drawings.

The same reference numerals in each drawing indicate the same member. In addition, specific structural and functional descriptions of the embodiments of the present invention are merely illustrative for the purpose of explaining the embodiments of the present invention, and unless otherwise defined, all terms used herein, including technical or scientific terms, are provided. They have the same meaning as generally understood by those skilled in the art to which the present invention pertains. Terms as defined in commonly used dictionaries should be interpreted as having meanings consistent with the meanings they have in the context of the related technology, and unless clearly defined in this specification, should not be interpreted in an idealized or overly formal sense. It is desirable not to.

Figure 1 schematically shows the configuration of a rapid heat curing formwork system according to a preferred embodiment of the present invention.

To be described with reference to Figure 1, the rapid heat curing formwork system according to a preferred embodiment of the present invention may include a formwork structure 100, a heating plate 200, a temperature sensor 300, and a control unit 500. Before describing each configuration of the rapid heat curing formwork system according to a preferred embodiment of the present invention with reference to the attached drawings, the rapid heat curing formwork system according to a preferred embodiment of the present invention is a method in which the heat generated from the fume plate 200 is This is a technology that is indirectly transmitted through the formwork structure 100 to the concrete poured on the area partitioned by the formwork structure 100, thereby shortening the curing time of concrete. Therefore, heating the form structure 100 through the heat generated from the heating plate 200 mentioned in the following description means that the concrete poured on the area defined by the form structure 100 by the heat applied to the form structure 100 It should be understood that heat is transferred to .

Figure 2 shows the shape of the formwork structure in the rapid heat curing formwork system according to a preferred embodiment of the present invention. Figure 2(a) shows the side shape of a formwork structure to which a single first frame is combined, and Figure 2(b) shows the A-A' section of Figure 2(a).

To be described with reference to FIGS. 1 and 2, the form structure 100 is provided with a metal plate 110 with one side facing the concrete pouring area and at least one rectangular frame shape coupled to the other side of the plate 110. It may include a first frame unit 120. Here, the form structure 100 may form a space where concrete is poured, and a plurality of form structures 100 are respectively disposed in areas corresponding to the floor surface and the wall surface and are connected to each other to accommodate the poured concrete. An accommodating space may be formed, and in some cases, the plate portion 110 of the single formwork structure 100 may be bent to form an accommodating space. Here, the plate portion 110 is provided in the shape of a metal plate, and as described above, one side faces the concrete pouring area, can support the poured concrete, and a heating plate 200, which will be described later, is attached to the heating plate 200. The heat generated from can also be transferred to the poured concrete. The first frame portion 120 is provided in a rectangular frame shape that is fixedly coupled to the rear of the plate portion 110 that supports the poured concrete, that is, the opposite side of the support surface, and can provide support to the plate portion 110. . At this time, as shown in FIG. 1, the first frame portion 120 may provide support to the plate portion 110 by having a plurality of plates 120, 120′ arranged in succession on the rear of the single plate portion 110. In 1, another first frame portion 120′ is shown adjacent to the first frame portion 120 provided in a rectangular frame shape, but the present invention is not limited to this, and a single first frame portion 120 The temporary plate part 110 may be provided in a grid frame shape to divide it into a plurality of rectangular areas. Here, the first frame parts 120, 120' have a penetrating hole through which the connection part 430 of the control unit 400, which will be described later, passes through the side corresponding to the longitudinal direction of the rectangular frame formed by the first frames 120, 120'. A hole H may be formed, and the formation location of the through hole H will be described in more detail in the description of the configuration of the fume plate 200.

In addition, the form structure 100 has a bar shape that connects a portion of the rear area of the plate portion 120 partitioned by the first frame portion 120 and the opposite surface in the width direction of the first frame portion 120. It may further include at least one second frame portion 130 provided. At this time, the second frame portion 130 may support the inner opposing surface of the first frame portion 120 to increase the supporting force of the first frame portion 120 supporting the plate portion 110. In addition, the second frame portion 130 does not interfere with the adhesion of the heating plate 200, which will be described later, to the rear area of the plate portion 110 partitioned by the first frame portion 120. To prevent this, it is preferable that the center part of the area facing the rear of the plate portion 110 is provided in a '['-shaped bar shape with the deletion.

Figure 3 shows the shape of the heating plate in the rapid heat curing formwork system according to a preferred embodiment of the present invention, and Figure 3 (a) partially shows the planar arrangement position of the electrode portion and the insulating portion based on the heating portion. , Figure 3(b) shows the laminated structure of the fume board based on the B-B' section of Figure 3(a).

1 to 3, the heating plate 200 is longitudinally adhered to the other surface area of the plate part 110 divided by the deleted area of the first frame part 120 and the second frame part 130. The plate part 110 can be heated by an electric signal, and may include a heating part 210, an electrode part 220, an insulating part 230, an insulating part 240, and a cover part 250. .

To explain with reference to (a) of FIGS. 1 and 3, the heating unit 210 is created in the form of paper by mixing carbon yarn, pulp, polyester synthetic fiber, carbon black, and other additives, and is generated by supplying electricity. It can be provided as a rectangular planar heating element that generates heat. Meanwhile, the heating part 210 may be inserted into the area formed by the deletion area of the first frame part 120 and the second frame part 130 and adhered to the plate part 110 through a silicone adhesive (P), At this time, the silicone adhesive P may be applied in a linear form with both ends open so that the heating unit 210 and the plate unit 110 are not adhered in a sealed state. This method of applying the silicone adhesive (P) of the heating part 210 is such that when the heating part 210 and the plate part 110 are bonded in a sealed state, when the heating part 210 is heated, the heating part 210 and the plate part This is to prevent a problem in which the heating part 210 may fall off from the plate part 110 due to expansion of the gas in the space formed by 110.

The electrode portion 220 includes first and second electrode portions 222 and 224 disposed at both longitudinal ends of the heating portion 210 and electrically connected to the heating portion 210, and is supplied from the control unit 400. The supplied electrical signal can be transmitted to the heating unit 210. Here, the first electrode portion 222 and the second electrode portion 224 of the electrode portion 220 may be disposed in the heating portion 210 with a distance of 30 cm or more. If the distance between the first electrode part 222 and the second electrode part 224 is less than 30 cm, the heating temperature of the heating part 210 may increase excessively compared to the heat generation control of the control unit 400, and the heating part 210 may be heated. (210) Heat control may be difficult. Accordingly, the first electrode portion 222 and the second electrode portion 224 may be disposed at both ends of the heating portion 210 in the longitudinal direction. In this case, the heating portion 210 also preferably has a length of 30 cm or more.

The insulating portion 230 is attached to an area of the other surface of the plate portion 210 adjacent to the electrode portion 220 and may be made of an epoxy film. Here, the insulating portion 230, as shown in FIGS. 3(a) and 3(b), insulates the electrode portion 220 and the plate portion 110 made of a gold material, thereby forming the control unit ( When electricity is supplied from 400 to the electrode unit 220, electricity leakage to the plate unit 110 can be prevented.

To be described with reference to (b) of FIG. 3 , the insulation unit 240 may be provided in the form of a sheet that surrounds the outer surface of the heating unit 210 and is adhered to the heating unit 210 . Here, the insulating part 240 is made of polyester to minimize heat loss toward the outer surface (= the opposite side of the adhesive surface) of the heating part 210, thereby increasing the heating efficiency of the plate part 110. It can be increased. At this time, the insulation unit 240 is bonded to the outer surface of the heating unit 210 using a silicone adhesive in order to maximize heat loss toward the outer surface of the heating unit 210, and the thickness of the heating unit 210 is It is preferably made of pure polyester (thermal conductivity 0.0041 W/mk) having a thickness of 15 to 20 times that of the polyester.

The cover part 250 is attached to cover the outer surface of the insulating part 240, has a thickness thinner than that of the insulating part 240, and is provided in the form of a film made of a harder material than the insulating part 240. You can. The cover portion 250 is preferably provided in the form of a PET (polyethylene terephthalate) film, and can protect the insulating portion 240 and the heating portion 210 from external impact.

The temperature sensor 300 can sense the temperature of the formwork structure 100. Here, the temperature sensor 300 may sense the temperature of the plate portion 110 by contacting the plate portion 110 adjacent to the area where the heating plate 200 is adhered.

Figure 4 shows an example of temperature management of the formwork structure by the control unit in the rapid heat curing formwork system according to a preferred embodiment of the present invention.

The control unit 400 can control the supply of electrical signals to the heating plate 200 according to the temperature sensed from the temperature sensor 300, and may include a confirmation unit 410, a control unit 420, and a connection unit 430. You can.

The confirmation unit 410 is connected to the temperature sensor 300 to check the temperature of the formwork structure 100.

The control unit 420 may generate an electrical signal for controlling heat generation of the heating unit 210 according to the temperature of the formwork 100 confirmed by the confirmation unit 410 and a preset target temperature value for each time. To explain with reference to the example of FIG. 4, curing of concrete through heating generally occurs in the order of displacement, temperature increase, maintenance, and cooling, and the control unit 420 sends an electric signal to the heating unit 210 for about 2 hours. Wait without supply. Thereafter, for about 2 hours, an electrical signal is generated by the heating unit 210 to generate heat so that the plate unit 110 reaches the target temperature value. At this time, the control unit 420 can control the intensity of heat generation according to the change in temperature of the plate part 110 confirmed through the confirmation unit 410, and the temperature of the plate part 110 confirmed by the confirmation unit 410 is the heat generation. Since it is due to heat conduction of the part 210, the control unit 420 controls the temperature of the plate part 110 confirmed by the confirmation unit 410 to reduce the heat generation intensity before it reaches the target temperature so that the temperature can be increased by heat conduction. can do. Thereafter, the control unit 420 generates an electrical signal that controls the heat generation intensity and heating cycle of the heating unit 210 so that the temperature of the plate unit 410 can be maintained constant for about 4 hours. Afterwards, the supply of electrical signals from the heating unit 210 is stopped so that thermal insulation curing can be achieved by the residual heat of the plate unit 110 heated by the heating unit 210.

The connection portion 430 is provided in the form of a pair of cables and includes a conductor portion 432 connected to the control portion 420 and a branch portion 434 branched from the conductor portion 432 and connected to the electrode portion 220. And, the electrical signal generated by the control unit 420 can be individually supplied to the first electrode portion 222 and the second electrode portion 224 of each electrode portion 220. Here, the connection portion 430 supplies electricity through the conductor portion 432, but since the electricity supplied through the conductor portion 432 is branched and supplied to the branch portion 434, each branch portion 434 is As shown in 1, when connected to each of the first electrode portion 222 and the second electrode portion 224 of the heating plates 200 and 200′, each fuming plate 200 and 200′ and the control unit 420 are connected in parallel, Even if a problem occurs in one of the two heating plates 200 and 200', an electrical signal can be supplied to the other heating plate 200 or 200' without a problem. At this time, in another first frame part 120' adjacent to the first frame part 120, the conductive wire part 432 connected to the control part 420 is an electrode of each heating plate 200, 200' adhered to the inner area. In order to prevent the branch portion 434 from being disconnected from the electrode portion 220 while being located adjacent to the portion 220, the branch portion 434 is attached to the electrode portion 220 of the heating plate 200, 200′ bonded to the inside. A through hole H through which the conductive wire portion 432 passes may be formed on the side of the adjacent first frame portions 120 and 120′. Therefore, in a state where the conductive wire portion 432 is inserted and mounted in the through hole (H), the electrical signal supplied from the control unit 420 is transmitted through the branch portion 434 connected to the electrode portion 220 of each heating plate 200. By transmitting the external exposure of the connection part 430 to a minimum, it is possible to prevent the connection part 430 from being damaged due to jamming with equipment or from being disconnected (short-circuited) from the electrical connection with the heating plate 200. .

That is, the rapid heat curing formwork system according to the present invention connects and supports the plate portion and the first frame portion provided in a rectangular frame shape in the longitudinal direction by removing the central area of the second frame portion facing the adhesive surface to which the heating plate is bonded, The applicable area of the heating plate is increased compared to the support area, which has the effect of enabling rapid heat curing of concrete over a large area.

In addition, the rapid heat curing formwork system according to the present invention is provided in a form in which an insulating part and a cover part are stacked in the opposite direction of the adhesive surface of the heating part, thereby minimizing heat emission to the outside rather than the form structure, thereby increasing heating efficiency. It has the effect of preventing damage to the heating part due to external shock.

The above-described embodiments of the present invention have been disclosed for illustrative purposes, and those skilled in the art will be able to make various modifications, changes, and additions within the spirit and scope of the present invention, and such modifications, changes, and additions will be possible. should be regarded as falling within the scope of the patent claims below.

100: Form structure
110: Panbu
120, 120′: 1st frame part
130, 130′: 2nd frame part
200: heating plate
210: heating unit
220: electrode part
222: First electrode portion
224: Second electrode portion
230: insulation part
240: insulation part
250: Cover part
300: Temperature sensor
400: Control unit
410: Confirmation unit
420: Control unit
430: connection part
432: Conductor part
434: Branch part
H: Through hole
S: compartment area
P: Silicone adhesive

Claims (7)

A formwork structure including a metal plate portion with one side facing the concrete pouring area and at least one first frame portion coupled to the other side of the plate portion and provided in a rectangular frame shape to support the plate portion;
At least one heating plate attached to the other surface area of the plate portion divided by the first frame portion and heating the plate portion by supplying an electric signal;
A temperature sensor that senses the temperature of the formwork structure; and
It includes a control unit that controls the supply of electrical signals to the heating plate according to the temperature sensed from the temperature sensor,
The control unit controls heat generation of the heating plate so that the temperature of the formwork structure confirmed through the temperature sensor reaches a preset target temperature value for each time,
The form structure interconnects a portion of the other surface area of the plate section partitioned by the first frame section and the inner opposing surface of the first frame section, and has a bar shape with one area opposite the area to which the heating plate is adhered deleted. It further includes at least one second frame unit provided,
The heating plate is,
a heating portion that is attached to the other surface area of the plate portion divided by the deleted area of the first frame portion and the second frame portion and heats the plate portion by an electric signal;
an electrode portion disposed at both ends of the heating portion and including first and second electrode portions electrically connected to the heating portion, and transmitting an electrical signal supplied from the control unit to the heating portion; and
It includes an insulating portion attached to a region of the other side of the plate portion adjacent to the electrode portion and provided with an epoxy film,
The heating part is formed in the form of paper by mixing carbon yarn, pulp, polyester synthetic yarn, and carbon black, and is applied linearly with openings at both ends on the central area of the adhesive surface so as not to be glued to the plate in a sealed state. It is attached to the other side of the plate with a silicone adhesive,
The control unit is,
A confirmation unit connected to the temperature sensor to check the temperature of the formwork structure;
a control unit that generates an electrical signal to control heat generation of the heating unit according to the temperature of the form structure confirmed by the confirmation unit and a preset target temperature value for each time; and
It includes a conductor part connected to the control unit and a branch part branched from the conductor part and connected to the electrode part, and the electric signal generated by the control unit is individually supplied to the first electrode part and the second electrode part of each electrode part. It includes a pair of connecting portions,
The first frame portion forms a through hole through which the conductive wire portion is placed so that each conductive portion of the pair of connecting portions is positioned adjacent to the first and second electrode portions of the heating plate bonded to the plate portion,
The heating plate further includes an insulating portion provided in the form of a sheet that surrounds and adheres to the outer surface of the heating portion,
The insulating part is bonded to the outer surface of the heating part through a silicone adhesive and is made of pure polyester having a thickness of 15 to 20 times the thickness of the heating part,
The heating plate is adhered to the outer surface of the insulating part, and further includes a film-shaped cover part made of a harder material than the insulating part.
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