KR102082269B1 - Winter concrete curing device with improved heating efficiency - Google Patents

Abstract

Disclosed is a concrete curing apparatus used in winter with improved heating efficiency. The disclosed concrete curing apparatus used in winter with improved heating efficiency comprises: a curing protection shield module; a chamber forming panel unit including a first chamber forming panel unit and a second chamber forming panel unit; a plurality of hot air injection nozzle units installed in the first chamber forming panel unit and the second chamber forming panel unit, respectively; a plurality of steam injection nozzle units installed in the first chamber forming panel unit and the second chamber forming panel unit, respectively; and a steam and hot air generator. According to the present invention, the heating efficiency of a concrete structure is improved, thereby rapidly and efficiently heating and curing the concrete structure.

Description

Winter concrete curing device with improved heating efficiency

The present invention relates to a winter concrete curing device for curing concrete in the cold in winter, and more specifically, to form a chamber forming panel portion at predetermined intervals on each of the inner wall and ceiling of the concrete structure, the chamber forming panel portion and the concrete structure The present invention relates to a winter concrete curing apparatus having improved heating efficiency for efficient and rapid heating and thermal curing of concrete structures by supplying and filling hot air and hot steam to the heating chamber formed therebetween.

In general, in the case of building buildings such as apartments and buildings in the cold winter, the concrete structure is formed by pouring concrete, and then the fossil fuel such as petroleum, coal, or building materials is burned to heat and heat the concrete structure by combustion heat.

However, the heating and thermal curing method using combustion heat by burning fossil fuels such as coal, petroleum, and building materials has been a major culprit of environmental pollution due to the high amount of carbon dioxide, and workers working in concrete structures are poisoned by combustion gases. In many cases, even suffocation deaths occur frequently. Therefore, when curing concrete structures by combustion methods, work in concrete structures has to be extremely limited.

In order to solve this problem, Korean Patent No. 10-0978005 discloses that an electric heater can be used to prevent the generation of soot of carbon dioxide, and the air heated to a high temperature by the electric heater can be blown using a small motor. Hot air blower is disclosed.

However, if the conventional electric hot air fan is simply installed in the concrete structure to perform heat insulating curing, the hot air generated from the electric hot air must spread to the entire area of the concrete structure and be completely filled in the entire area of the concrete structure to achieve a substantial heat insulating curing. Because it can be, the conventional electric heat blower method takes a lot of time to heat the concrete heating insulation curing and had a problem that is not efficient.

Patent Registration 10-1698493 Patent Registration 10-0366144 Patent Registration 10-0978005

The present invention was devised to solve the conventional problems as described above, comprising a chamber forming panel portion at predetermined intervals on each of the inner wall and the ceiling of the concrete structure, the heating chamber formed between the chamber forming panel portion and the concrete structure The purpose of the present invention is to provide a winter concrete curing device with improved heating efficiency for efficient and rapid heating and thermal curing of concrete structures by supplying and filling hot air and high temperature steam.

In addition, the present invention prevents the occurrence of dangerous gases by preventing the occurrence of combustion gas compared to the hot air of the fuel combustion method by generating hot air with a heating wire using electricity, and constitutes a steam and hot air generator having the function of generating hot steam with hot air In addition, by supplying the hot air and steam generated in the steam and the hot air generator to the heating chamber, respectively, an object of the present invention is to provide a winter concrete curing apparatus with improved heating efficiency to achieve efficient concrete heating insulation curing.

Winter concrete curing device is improved heating efficiency of the present invention for achieving the above object in the concrete curing device for heating and curing curing by supplying hot air in the concrete structure to be cured in the winter, reinforcement film covering the outside of the concrete structure module; A first chamber forming panel part installed to be spaced apart from the sidewall of the concrete structure by a predetermined distance to form a first heating chamber filled with hot air and high temperature steam between the sidewall of the concrete structure, and spaced apart from the ceiling of the concrete structure A chamber forming panel portion installed to include a second chamber forming panel portion formed between the ceiling of the concrete structure and a second heating chamber filled with hot air and hot steam; A plurality of hot air spray nozzle units which are respectively installed in the first chamber forming panel portion and the second chamber forming panel portion to inject hot air into the first heating chamber and the second heating chamber; A plurality of steam injection nozzle units which are respectively installed in the first chamber forming panel portion and the second chamber forming panel portion to inject and supply high temperature steam to the first heating chamber and the second heating chamber; And steam and hot air generators for generating hot air and high temperature steam, supplying hot air to each of the plurality of hot air spray nozzle units, and supplying hot steam to each of the plurality of steam spray nozzle units. Hot air and hot steam generated from a hot air generator are injected through the plurality of hot air spray nozzle units and the plurality of steam spray nozzle units and filled in the first heating chamber and the second heating chamber to heat and insulate the heating of the concrete structure. It is configured to be made, each of the front surface of the first chamber forming panel portion facing the sidewall of the concrete structure and the front surface of the second chamber forming panel portion facing the ceiling of the concrete structure heat insulation of the concrete structure by radiant heat It is configured to install a planar heating element to promote curing, in the concrete structure A panel support frame installed in the unit, and each of the first chamber forming panel portion and the second chamber forming panel portion to the panel supporting frame, and adjusting the distance of the first chamber forming panel portion to the sidewall of the concrete structure. And a plurality of gap adjusting means formed of a hydraulic cylinder for adjusting a distance of the second chamber forming panel portion with respect to the concrete structure ceiling, wherein the hot air spray nozzle unit comprises the first chamber forming panel portion. And a pin insertion passage formed to penetrate each of the second chamber forming panel portions, and formed inside the front end portion so as to be connected to the pin insertion passage, and spraying hot air toward the concrete structure. It is formed to be connected to the flow path and the front injection flow path to direct hot air toward the first chamber forming panel portion and the second chamber forming panel portion. A hot-air nozzle body provided with a lateral jet flow path for inclining the injection into the room; It is installed at the rear end of the hot air nozzle body, the hot air supply passage is formed to be connected to the pin insertion passage to provide hot air to the pin insertion passage, one side is installed to be connected to the hot air supply passage in the steam and hot air generator A hot air supply block having a hot air supply port for supplying hot air to the hot air supply passage; An opening / closing pin inserted into the pin insertion passage to block or open a rear end of the front injection passage while moving forward and backward; The flow rate is inserted into the hot air supply passage, and configured to move back and forth along the opening and closing pins, and adjust the opening and closing degree of the outlet of the hot air supply passage to adjust the flow rate of hot air supplied to the pin insertion passage through the hot air supply passage. Control pins; And a control pin driving member connected to one side of the flow regulating pin in a rack-pinion manner to move the flow regulating pin forward or backward according to a rotational direction. The steam and hot air generator is configured to include an upper portion of the flow regulating pin. A main body having a tubular shape, an air inlet is formed at one lower side thereof, a water inlet is formed at the other lower side thereof, and an upper body having a steam outlet connected to the steam injection nozzle unit by a steam transfer hose; A lid coupled to cover the open top of the device body and having a hot air outlet formed at the center thereof connected to the hot air spray nozzle unit by a hot air transfer hose; Consists of a cylindrical shape is installed so as to be vertically disposed in the interior of the device body is formed so that a plurality of coil seating grooves formed in a circular ring shape along the inner circumference to be spaced apart a predetermined interval up and down, the air introduced through the bottom proceeds upwards A heating member made of a ceramic material to generate hot hot air while discharging the generated hot air to the hot air outlet; A coil-type heating wire installed to be inserted into the coil seating groove and seated therein and heating the heating member while being heated by an electric supply; A fan motor installed inside the device main body and sucking outside air through the air inlet to supply air into the heating member; A steam connecting the water inlet and the steam outlet to penetrate the heating member up and down and heated to a high temperature by the heating member to generate hot steam from water introduced through the water inlet and discharged to the steam outlet. Generating tube; Spirally wound on the upper surface of the lid and one side is connected to the water storage tank, the other side is installed to be connected to the water inlet, to supply the water received in the water storage tank to the water inlet, through the hot air outlet A preheating tube which heat-exchanges with the lid heated by the discharged hot air and supplies the water to the water inlet while preheating the water to a predetermined temperature; And a water transfer pump installed on a connection flow path connecting the water storage tank and the preheating pipe to transfer the water contained in the water storage tank to the preheating pipe, wherein the device body has a first cooling air inlet hole. And a second cooling air inlet hole connected to the coil seating groove on the outer circumferential surface of the heating member and configured to supply external air introduced through the first cooling air inlet hole to the coil seating groove. The shutter member is configured to simultaneously open and close the first cooling air inlet hole and the second cooling air inlet hole while moving forward or backward according to the driving of the cylinder module installed on the outside thereof. The first cooling air inflow hole and the second cooling air inflow hole are opened so that external air flows into the first cooling air inflow hole and the first cooling air inflow hole. It is supplied to the coil seating groove through the hole, characterized in that configured to cool the heating wire installed in the coil seating groove to prevent overheating damage to the heating wire.

According to the above, the heating chamber is formed only in the inner wall of the concrete structure and a part of the vicinity of the ceiling of the entire internal area of the concrete structure, compared to the existing heat insulating curing by the hot air supply, and thus preferentially and intensively the hot air in the heating chamber. By supplying the super-heated steam, the heating efficiency of the concrete structure is improved to have a fast and efficient heating insulation curing of the concrete structure.

In addition, the present invention constitutes a steam and hot air generator that generates steam and hot air together, and the steam and hot air generators supply hot air and high temperature steam to the inner wall of the concrete structure and the heating chamber near the ceiling, so that each of the separate hot air fans Not only do not need to have a steam generator and not only reduce the operating cost, but also the operator does not need to install the hot air and steam generator in the concrete structure, so that the installation work can be solved.

In addition, the present invention is provided with a planar heating element on the front surface of the chamber forming panel portion for forming the heating chamber on the inner wall and the ceiling of the concrete structure, the concrete by the heat of radiant heat of the planar heating element as well as hot air and hot steam supplied to the heating chamber The heat is applied to the structure, there is an effect that the heating insulation curing can be made more efficiently.

In particular, since the distance between the chamber forming panel portion and the concrete structure is configured to be adjustable, the size of the heating chamber can be easily adjusted, and the intensity of radiant heat transmitted by the planar heating element can be easily adjusted to the concrete structure. There is an effect that can be precisely and easily control the heating temperature for.

1 is an exemplary view of the winter concrete curing apparatus improved heating efficiency according to an embodiment of the present invention,
2 is an enlarged view of a portion of FIG. 1;
3 is a view showing a specific configuration for the hot air spray nozzle unit shown in FIG.
4 is a view showing a specific configuration for the steam injection nozzle unit shown in FIG.
5 is a view showing a specific configuration of the steam and hot air generator of the present invention shown in FIG.
Figure 6 is a perspective view showing a specific configuration of the heating member and the steam generating tube in Figure 5,
7 is a view showing a state of the heating member of the present invention as viewed from the top,
8 is a view showing the installation form of the preheating tube shown in FIG. 5 as viewed from the top.

Objects, other objects, features and advantages of the present invention will be readily understood through the following preferred embodiments associated with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided to ensure that the disclosed contents are thorough and complete, and that the spirit of the present invention can be sufficiently delivered to those skilled in the art.

In the present specification, when a component is mentioned as being on another component, it means that it may be formed directly on the other component or a third component may be interposed therebetween. In addition, in the drawings, the thickness of the components are exaggerated for the effective description of the technical content.

Embodiments described herein will be described with reference to cross-sectional views and / or plan views, which are ideal exemplary views of the present invention. In the drawings, the thicknesses of films and regions are exaggerated for effective explanation of technical content. Therefore, the shape of the exemplary diagram may be modified by manufacturing techniques and / or tolerances. Therefore, the exemplary embodiments of the present invention are not limited to the specific forms shown, but include changes in forms generated according to manufacturing processes. For example, the etched regions shown at right angles may be rounded or have a predetermined curvature. Thus, the regions illustrated in the figures have properties, and the shape of the regions illustrated in the figures is intended to illustrate a particular form of region of the device and is not intended to limit the scope of the invention. Although terms such as first and second are used to describe various components in various embodiments of the present specification, these components should not be limited by such terms. These terms are only used to distinguish one component from another. The embodiments described and illustrated herein also include complementary embodiments thereof.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, the words 'comprises' and / or 'comprising' do not exclude the presence or addition of one or more other components.

In describing the following specific embodiments, various specific details are set forth in order to explain and understand the invention in more detail. However, one of ordinary skill in the art can understand that the present invention can be used without these various specific details. In some cases, it is mentioned in advance that parts of the invention that are commonly known and do not relate significantly to the invention are not described in order to prevent confusion in explaining the present invention without cause.

Hereinafter, with reference to the drawings, it will be described the winter concrete curing apparatus improved heating efficiency according to an embodiment of the present invention.

1 and 2, the winter concrete curing device of the present invention, the membrane module 110, the chamber forming panel portion (210a, 210b), hot air spray nozzle unit 300, steam spray nozzle unit 400, It is configured to include a steam and hot air generator 500.

The reinforcement membrane module 110 is to protect the concrete structure 10 from the cold of the winter covering the outside of the concrete structure to be cured, the reinforcement membrane support frame 111 is installed around the concrete structure 10 In addition, the support frame 111 may be configured by installing a supplementary film 113.

The chamber forming panel portions 210a and 210b are configured to include a first chamber forming panel portion 210a and a second chamber forming panel portion 210b.

The first chamber forming panel portion 210a is installed to face the concrete structure 10 sidewalls at a predetermined interval so as to form a first heating chamber c1 between the sidewalls of the concrete structure 10. The second chamber forming panel portion 210b is installed to face the ceiling of the concrete structure 10 at a predetermined interval so as to form a second heating chamber c2 between the ceiling and the ceiling of the concrete structure 10.

In the present invention, the panel support frame 220 is installed inside the concrete structure 10, a plurality of gap adjusting means 230 is formed on the side and top of the panel support frame 220, the gap adjusting means 230 ) Is configured such that the first chamber forming panel portion 210a and the second chamber forming panel portion 210b are installed.

A plurality of gap adjusting means 230 is composed of a hydraulic cylinder unit, according to the expansion and contraction of the gap adjusting means 230, the first chamber forming panel portion 210a is advanced to move closer to or away from the side wall of the concrete structure (10) Alternatively, the distance of the first chamber forming panel portion 210a with respect to the side wall of the concrete structure 10 is adjusted, and the second chamber forming panel portion 210b may be adjusted according to the stretching operation of the gap adjusting means 230. May be configured to adjust the distance of the second chamber forming panel portion 210b with respect to the ceiling of the concrete structure 10 by moving forward or backward to approach or move away from the ceiling of the concrete structure 10.

The hot air spray nozzle unit 300 is installed in each of the first chamber forming panel portion 210a and the second chamber forming panel 210b, respectively, and receives the hot air from the steam and the hot wind generator 500, and receives the first heating chamber ( The hot air is filled in the first heating chamber c1 and the second heating chamber c2 by spraying the c1) and the second heating chamber c2 so that heating and curing of the concrete structure 10 may be performed.

In addition, a plurality of steam injection nozzle units 400 are respectively installed in the first chamber forming panel portion 210a and the second chamber forming panel 210b, and are supplied with high temperature steam from the steam and hot air generators 500. By spraying the heating chamber (c1) and the second heating chamber (c2) to fill the first heating chamber (c1) and the second heating chamber (c2) with high-temperature steam to heat the thermal insulation curing for the concrete structure (10) Can be.

When only the hot air spray nozzle unit 300 is installed, a rapid moisture evaporation of the concrete structure 10 occurs, so that high-quality curing does not proceed, together with the hot air through the hot air spray nozzle unit 300, the steam spray nozzle unit 400. At the same time the supply of high temperature steam through), high quality heat insulation curing will be achieved.

A plurality of hot air spray nozzle unit 300 and the steam spray nozzle unit 400 of the present invention is formed in each of the first chamber forming panel portion 210a and the second chamber forming panel portion 210b, the first chamber forming panel The parts 210a and the second chamber forming panel parts 210b are configured to be alternately installed at predetermined intervals.

Steam and hot air generator 500 is composed of an electric hot air fan capable of generating a high temperature steam, it is configured to be connected to each hot air jet nozzle unit 300 by a hot air transfer hose (h1) to the hot air jet nozzle unit 300 It is configured to be connected to each steam injection nozzle unit 400 by a steam transfer hose (h2) is configured to supply high temperature steam to the steam injection nozzle unit (400).

In the present invention as described above, the first heating chamber c1 is formed between the inner wall of the concrete structure 10 by the first chamber forming panel portion 210a, and the second chamber forming panel portion 210b. The second heating chamber (c2) is formed between the ceiling of the concrete structure 10, the hot air and hot steam in the steam and hot air generator 500, the first chamber forming panel portion 210a and the second chamber forming panel portion Filled in the first heating chamber (c1) and the second heating chamber (c2) through the hot air spray nozzle unit 300 and the steam spray nozzle unit 400 installed in (210b) for the concrete structure 10 It is a structure in which heating and heat curing is performed. As compared with the method in which hot air is transferred from the vicinity of the hot air to the entire area of the concrete structure as compared with the conventional method, the heat efficiency of the hot air is transmitted to the concrete structure. Concrete heating Onyang and life is able to be achieved, as well as to easily and accurately control the heating temperature of the heat insulating curing, it is possible to reduce the power consumption according to an efficient operation of the yeolpunggi.

That is, in the conventional method, when hot air is discharged from the hot air fan installed in the concrete structure, it takes a long time until the hot air is diffused from the area where the hot air fan is installed and the hot air is completely filled in the entire area inside the concrete structure. Since the proper curing of the concrete structure can proceed after the hot air is completely filled in the area, the heating efficiency of the concrete structure is very inefficient, and thus there is a problem that the hot air fan must be operated inefficiently for a long time.

However, the present invention forms the first heating chamber (c1) between the inner wall of the concrete structure 10 by the first chamber forming panel portion 210a, and the concrete by the second chamber forming panel portion 210b. In the state in which the second heating chamber c2 is formed between the ceiling and the structure 10, the hot air and the hot steam generated from the steam and the hot air generator 500 occupy a very small part of the concrete structure compared to the entire area inside the concrete structure. Occupies and directly supplies the first heating chamber (c1) and the second heating chamber (c2), which can directly transfer the heat energy required for curing to the concrete structure, thereby greatly improving the heating efficiency of the concrete structure, It is possible to improve the operating efficiency for the steam and hot air generator (500).

Meanwhile, referring to FIGS. 3 and 4, the front surface of the first chamber forming panel portion 210a of the present invention, that is, the front surface of the first chamber forming panel portion 210a facing the inner wall of the concrete structure 10. The planar heating element 214 may be installed to provide heat radiation due to the heat generated by the planar heating element 214 to the inner wall of the concrete structure 10 to promote heating and curing of the concrete structure 10.

Similar to the planar heating element 214 of the first chamber forming panel portion 210a, the planar heating element is also provided on the front surface of the second chamber forming panel 210b facing the ceiling of the concrete structure 10, so as to generate heat of the planar heating element. By providing radiant heat to the ceiling of the concrete structure 10 can be configured to promote heating and heat curing for the concrete structure (10).

At this time, the intensity of the radiant heat transmitted to the concrete structure 10 by the heating of the planar heating element 214 may be adjusted according to the adjustment of the gap adjusting means 230.

Hereinafter, the hot air spray nozzle unit 300 of the present invention will be described in detail with reference to FIGS. 2 and 3.

The hot air spray nozzle unit 300 is connected to the steam and the hot air generator 500 and the hot air transfer hose h1 to supply the hot air supplied from the steam and the hot air generator 500 to the first heating chamber c1 and the second heating unit. Injection into the chamber c2 causes the first heating chamber c1 and the second heating chamber c2 to be in a high temperature state.

The hot air spray nozzle unit 300 includes a hot air nozzle body 310, a hot air supply block 320, an opening and closing pin 330, a flow control pin 340, and an adjustment pin driving member 345.

The hot air nozzle body 310 is installed to penetrate the chamber forming panel portions 210a and 210b, and is configured to protrude forward of the chamber forming panel portions 210a and 210b.

A pin insertion passage 312 is formed inside the rear end of the hot air nozzle body 310, and a front injection passage 314 is formed inside the front end to spray the hot air straight toward the concrete structure 10. It is connected to the injection passage 314 and configured to form a plurality of side injection passage 316 for injecting the hot air inclined toward the chamber forming panel portions (210a, 210b). At this time, the pin insertion passage 312 is configured to have a larger inner diameter than the front injection passage 314.

The hot air supply block 320 is installed at the rear end of the hot air nozzle body 310, and is connected to the pin insertion passage 312 to form a hot air supply passage 321 for supplying hot air to the pin insertion passage 312. The side portion is configured such that a hot air supply port 323 is connected to the hot air supply passage 321. The hot air supply port 323 is connected to the hot air transfer hose h1 and configured to supply hot air from the steam and the hot air generator 500.

The opening and closing pin 330 is a front end portion is inserted into the pin insertion passage 312, the rear end of the drive means consisting of an electric cylinder or the like installed in the casing 334 fixed to the rear of the chamber forming panel portions (210a, 210b) ( It is installed to be connected to the 332, it is configured to open and close the rear end of the front injection passage 314 by moving forward or backward in accordance with the expansion and contraction of the drive means (332).

When hot air is supplied from the steam and hot air generator 500 through the hot air transfer hose h1 in a state where the rear end of the front injection passage 314 is opened by the opening / closing pin 330, the hot air is supplied to the hot air supply port 323. The hot air supply passage 321 and the pin insertion passage 312 may be injected from the front injection passage 314 and the side injection passage 316.

According to the present invention, the hot air is injected toward the concrete structure 10 through the front injection passage 314 and filled in the heating chambers c1 and c2, and the chamber forming panel portions 210a and 210b are provided through the side injection passage 316. It is injected obliquely toward, and hitting the chamber forming panel portion (210a, 210) and the flow path is made to form a vortex, so that the heating chamber (c1, c2) is quickly brought to a high temperature state by hot air.

In addition, the hot air injected from the side injection passage 316 is injected to the planar heating element 214 installed on the front of the chamber forming panel portion 210a, 210b substantially, thereby, the power supply to the planar heating element 214 is stopped. Even if it is possible to prevent the temperature of the planar heating element 214 is sharply reduced.

Flow rate control pin 340 is a front end portion is inserted into the hot air supply passage 321, the opening and closing pin 330 is configured to be moved back and forth along the opening and closing pin 330. The flow rate adjusting pin 340 moves forward and backward along the opening / closing pin 330 to adjust the opening and closing degree of the outlet of the hot air supply passage 321 to be introduced into the pin insertion passage 312 through the hot air supply passage 321. It is configured to adjust the flow rate of hot air.

The adjustment pin drive member 345 is composed of a pinion, and is configured to be connected to one side of the flow control pin 340 in a rack-pinion manner, and the adjustment pin drive member 345 is formed by a rotation shaft of a drive motor (not shown). Is connected and configured to be capable of forward or reverse rotation depending on the drive of the drive motor. That is, the adjustment pin drive member 345 is composed of a pinion, one side of the flow control pin 340 is provided with a rack before and after, one side of the control pin drive member 345 and the flow control pin 340 is rack- By being configured to be connected in a pinion manner, the flow control pin 340 is forward or backward along the opening and closing pin 330 according to the forward or reverse rotation of the control pin drive member 345, the outlet side of the hot air supply passage 321 By adjusting the opening and closing degree of the hot air flow rate is injected through the front injection passage 314 and the side injection passage 316 can be adjusted.

2 and 4, the steam injection nozzle unit 400 of the present invention is connected through a steam and hot air generator 500 and a steam transfer hose (h2) is a high temperature supplied from the steam and hot air generator (500) Steam is injected into the first heating chamber c1 and the second heating chamber c2 so that the first heating chamber c1 and the second heating chamber c2 are filled with high temperature steam to be in a high temperature state.

The steam injection nozzle unit 400 is configured to include a steam nozzle body 410, a steam supply block 420, and a second opening / closing pin 430.

The steam nozzle body 410 is installed to penetrate the chamber forming panel portions 210a and 210b and is configured to protrude forward of the chamber forming panel portions 210a and 210b.

A second pin insertion passage 412 is formed inside the rear end of the steam nozzle body 410, and a first steam injection passage 414 for spraying hot steam straight toward the concrete structure 10 is formed inside the front end. Is formed. In addition, a spiral internal flow passage 416 and a spiral connected to the inside of the front end portion of the steam nozzle body 410 are connected to the second pin insertion flow passage 412 and are formed to spirally wrap around the first steam injection flow passage 414. It is connected to the internal passage 416 is configured to include a plurality of lateral steam injection holes 417 to radially inject the hot steam to the side of the steam nozzle body 410. In the present embodiment, the second pin insertion channel 412 is configured to have a larger inner diameter than the first steam injection channel 414.

The steam supply block 420 is installed at the rear end of the steam nozzle body 410 and is connected to the second pin insertion passage 412 to supply the high temperature steam to the second pin insertion passage 412. Is formed, and is configured to form a steam supply port 423 connected to the steam supply passage 421 on one side. The steam supply port 423 is connected to the steam transfer hose h2 and configured to supply hot steam from the steam and hot air generator 500.

The second opening pin 430 has a front end is inserted into the second pin insertion passage 412, the rear end is an electric cylinder that is installed in the second casing 434 fixed to the rear of the chamber forming panel (210a, 210b) It is installed so as to be connected to the second driving means 432, etc., and is configured to open or close the rear end of the first steam injection flow path 414 by moving forward or backward in accordance with the expansion and contraction of the second driving means 332.

When the rear end of the first steam injection flow path 414 is opened by the second opening and closing pin 430, when the high temperature steam is supplied from the steam and the hot air generator 500 through the steam transfer hose h2, the high temperature steam After passing through the steam supply port 423, the steam supply passage 421 and the second pin insertion passage 412, it is sprayed toward the concrete structure 10 through the first steam injection passage 414, and also, inside the spiral It is injected to the side through the flow path 416 and the side steam injection hole 417 is filled with high temperature steam in the heating chamber (c1, c2) to form a high temperature state.

On the other hand, in the present invention, when the rear end of the first steam injection passage 414 is blocked by the second opening and closing pin 430, when the high temperature steam is supplied from the steam and hot air generator 500 through the steam transfer hose (h2) After the high temperature steam passes through the steam supply port 423, the steam supply passage 421, and the second pin insertion passage 412, the high temperature steam is not supplied to the first steam injection passage 414, and the second pin insertion passage 412 is not supplied. It is supplied only to the spiral inner passage 416 connected to the) may be configured to be injected laterally through the side vapor injection hole (417).

2, 5 to 8, the steam and hot air generator 500 generates hot air and high temperature steam, and is connected to the hot air spray nozzle unit 300 through a hot air transfer hose h1 to hot air. It is supplied to the injection nozzle unit 300, is connected to the steam injection nozzle unit 400 through the steam transfer hose (h2) is configured to supply high temperature steam to the steam injection nozzle unit (400).

Steam and hot air generator 500 is configured to include a device body 510, the lid 520, the heating member 530, the heating wire 540, the steam generating pipe 550, the preheating pipe 590.

The device body 510 is formed in a cylindrical shape with an open top, an air inlet 512a is formed at one lower side, a water inlet 515 is formed at the other lower side, and a steam outlet 516 is formed at an upper side. The steam outlet 516 is configured to be connected to the steam transfer hose h2.

Inside the device body 510 is provided with a support disk 511 through which the hollow part is formed, and a seating tube 511a formed of a circular tube is formed on the upper surface of the support disk 511, and the seating tube 511a is heated. The member 530 is configured to be inserted.

In addition, the inside of the device body 510 is configured so that one side is connected to the air inlet 512, the other side is formed with an air supply passage 512 connected to the hollow portion of the support disk 511, the air supply passage The fan motor 514 is installed on the 512 to suck the outside air through the air inlet 512 to blow air into the heating member 530 installed on the support disk 511.

The lid 510 is coupled to cover the open top of the device body 510, and a hot air outlet 522 is provided at the center thereof, and the hot air outlet 522 is configured to be connected to the hot air transfer hose h1.

The heating member 530 is made of a ceramic material and has a circular cylindrical shape opened up and down. The lower portion communicates with the hollow portion of the support disk 511 and the upper portion is configured to communicate with the hot air outlet 522.

An inner circumferential surface of the heating member 530 is configured to have a coil seating groove 531 formed in an arc shape, and a plurality of coil seating grooves 513 are formed on the inner circumferential surface of the heating member 530 to be spaced apart by a predetermined interval in a vertical direction. It is configured to.

In addition, a lower ring groove 533 is formed on the lower surface of the heating member 520, an upper ring groove 534 is formed on the upper surface, and a plurality of pipe insertion holes connecting the lower ring groove 533 and the upper ring groove 534 ( 535 is formed through. The plurality of pipe insertion holes 535 are configured to be vertically formed at predetermined intervals along the arcs of the lower ring groove 533 and the upper ring groove 534.

The heating wire 530 is made of a conventional coil heater wire that generates heat according to the application of electricity, is formed in a circular ring shape, and is installed to be inserted and seated in the coil seating groove 531.

In the above-described configuration, the heating member 530 is heated to a high temperature by the heat generation of the heating wire 530, and the external air introduced through the air inlet 512a passes through the inside of the heated heating member 530. After the hot air is discharged through the hot air outlet 522, the hot air discharged through the hot air outlet 522 is configured to be supplied to the hot air spray nozzle unit 300 through the hot air transfer hose h1.

The steam generating pipe 550 heats the water introduced through the water inlet 51 to a high temperature to generate high temperature steam, and discharges the generated steam to the steam outlet 516, the lower ring pipe 552, the upper It is configured to include a ring-shaped tube 555, a plurality of vertical tubes 558.

The lower ring tube 552 is installed to be seated in the lower ring groove 533, one side is provided with a lower connecting pipe 533, the lower connecting pipe 533 is configured to be connected to the water inlet 515.

The upper ring tube 555 is installed to be inserted and seated in the upper ring groove 534, one side is provided with an upper connecting pipe 556, the lower connecting pipe 556 is configured to be connected to the steam outlet 516. In addition, the upper ring-shaped tube 555 is configured to be formed at a predetermined interval along the circumferential socket portion 555a extending downward. Here, the socket portion 555a is configured such that the upper end of the vertical pipe 558 is inserted into and coupled to the vertical pipe 558 and the upper ring-shaped pipe 555.

The vertical pipe 558 is composed of a plurality, it is configured to extend from the lower ring-shaped pipe 552 to be installed at a predetermined interval circumferentially. The vertical tube 558 is inserted into the tube insertion hole 535 is configured to penetrate the heating member 530 up and down.

In the present invention, as shown in Figure 6, the vertical pipe 558 and the lower ring-shaped pipe 522 may be configured integrally, in this case, the vertical pipe 558 in the lower portion of the heating member 530 tube insertion hole ( The lower ring tube 552 is inserted into the lower ring groove 533 so that the upper ring groove 534 is seated in the upper ring groove 534 while the upper ring groove 534 is inserted into the lower ring groove 534. It can be installed by fitting the socket portion (555a) of the upper ring-shaped pipe (555).

The preheating tube 590 is formed to be spirally wound on the upper surface of the lid 520, one side 592 is configured to be connected by the water storage tank 620 and the connection flow path 615, the other side 593. Is configured to be connected to the water inlet 515. The hot air is discharged through the hot air outlet 522 so that the lid 520 may be at a high temperature, and the preheating tube 590 installed to be in contact with the upper surface of the lid 520 is also heated. Accordingly, when the water supplied from the water storage tank 620 passes the preheating tube 590, the water may be preheated to a predetermined temperature, and the preheated water may be supplied to the steam generating tube 550 through the water inlet 515. Can be.

The water transfer pump 610 is installed on the connection passage 615 connecting the water storage tank 620 and the preheating pipe 590 to transfer the water received in the water storage tank 620 to the preheating pipe 590. Configured to supply.

In the above configuration, the water supplied from the water storage tank 620 is preheated to a predetermined temperature while passing through the preheating pipe 590, the preheated water is supplied to the steam generating pipe 550 through the water inlet 515 The high temperature steam is generated while sequentially passing through the lower ring pipe 552, the plurality of vertical pipes 558, and the upper ring pipe 555 of the steam generating pipe 550. The generated high temperature steam is configured to be supplied to the steam spray nozzle unit 400 through the steam outlet 516 and the steam transfer hose h2.

On the other hand, the steam and hot air generator 500 of the present invention is a large capacity, damage may occur due to overheating of the heating wire 540, in order to solve this problem, the heat of the external air during the heating of the heating wire 540 heat 540 ) To cool the heating wire 540 to a temperature at which no overheating damage occurs.

To this end, a first cooling air inlet hole 518 is formed on one side of the device body 510, a plurality of second cooling air connected to each coil seating groove 531 up and down on the outer surface of the heating member 530. Inlet hole 538 is configured to be formed.

In addition, a cylinder module 577 made of a pneumatic cylinder, an electric cylinder, or the like is installed outside the device body 510, and a shutter member 570 is installed on the expansion rod of the cylinder module 577, thereby providing a cylinder module 577. According to the stretching operation of the), the shutter member 570 is configured to open or block the first cooling air inlet 518 and the second cooling air inlet 538 together.

The shutter member 570 is formed in a vertically long rectangular piece shape and extends backward from the first opening and closing plate 571 and the first opening and closing plate 571 to open and close the plurality of second cooling air inlet holes 538. It is configured to include an extension bar 575 and a second opening and closing plate 573 in the form of a circular disk coupled to the rear end of the extension bar 575 and to open and close the first cooling air inlet hole 518. At this time, the female screw portion 573a is provided at the center of the rear surface of the second opening and closing plate 573, and is configured to be screwed with the expansion rod of the cylinder module 577.

With the above configuration, when the expansion rod of the cylinder module 577 extends, as shown in FIG. 5, the first opening / closing plate 571 blocks the plurality of second cooling air inlet holes 538, and the second opening / closing with it. The plate 573 blocks the first cooling air inlet hole 518.

On the other hand, when the expansion and contraction rod of the cylinder module 577, the first opening and closing plate 571 and the second opening and closing plate 573 retreat at the same time, the first cooling air inlet hole 518 and the plurality of second cooling As the air inlet hole 538 is opened together, external air flows into each coil seating groove 531 through the first cooling air inlet hole 518 and the plurality of second cooling shared inlet holes 538, thereby providing a coil seating groove ( The heating wire 540 installed at 531 may be cooled to a predetermined temperature so as not to be damaged.

Meanwhile, the fan motor 514 is operated to drive the cylinder module 577 in a state in which the hot air escapes through the hot air outlet 522, so that the first opening and closing plate 571 and the second opening and closing plate 573 are the first. When the cooling air inlet hole 518 and the plurality of second cooling air inlet holes 538 are opened and closed, the first air is cooled by the flow of hot air flowing from the lower part of the heating member 530 to the upper part. A suction force to be introduced into each coil seating groove 531 through the inlet hole 518 and the plurality of second cooling air inlet holes 538 may be generated. Accordingly, the heating wire 540 generates heat to generate hot air. During the process, the shutter member 570 controls the cylinder module 577 to open and close the first cooling air inlet 518 and the plurality of second cooling air inlet 538, thereby overheating the heating wire 540. While preventing the damage caused by the hot air can be continuously generated and supplied to the hot air jet nozzle unit (300).

While the invention has been shown and described in connection with preferred embodiments for illustrating the principles of the invention, the invention is not limited to the configuration and operation as such is shown and described. Rather, it will be apparent to those skilled in the art that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes, modifications, and equivalents should be considered to be within the scope of the present invention.

10 ... concrete structures
110.Film Film Module
111. Support film support frame
113 ... Reservoir
210a, 210b ... chamber forming panel part
220 ... panel support frame
230 ... spacing means
300 ... Hot Air Spray Nozzle Unit
310 hot air nozzle body
320 ... hot air supply block
330 ... opening pin
340.Flow control pin
345.Adjusting pin drive member
Steam injection nozzle unit
Steam nozzle body
420 Steam Supply Blocks
430 ... second opening pin
500 ... Steam and Hot Air Generators
510 ... Base
520 lid
530 Heating element
540 ... heating wire
550 ... Steam generator
590 Preheater
610..Transfer Pump
620 ... water storage tank

Claims (1)

In the concrete curing device for curing heat and heat by supplying hot air in the concrete structure to be cured in winter,
Retention membrane module to cover the outside of the concrete structure;
A first chamber forming panel part installed to be spaced apart from the sidewall of the concrete structure by a predetermined distance to form a first heating chamber filled with hot air and high temperature steam between the sidewall of the concrete structure, and spaced apart from the ceiling of the concrete structure A chamber forming panel portion installed to include a second chamber forming panel portion formed between the ceiling of the concrete structure and a second heating chamber filled with hot air and hot steam;
A plurality of hot air spray nozzle units which are respectively installed in the first chamber forming panel portion and the second chamber forming panel portion to inject hot air into the first heating chamber and the second heating chamber;
A plurality of steam injection nozzle units which are respectively installed in the first chamber forming panel portion and the second chamber forming panel portion to inject and supply high temperature steam to the first heating chamber and the second heating chamber;
And steam and hot air generators for generating hot air and high temperature steam, supplying hot air to each of the plurality of hot air spray nozzle units, and supplying high temperature steam to each of the plurality of steam spray nozzle units.
The hot air and hot steam generated from the steam and the hot air generator are injected through the plurality of hot air spray nozzle units and the plurality of steam spray nozzle units and filled in the first heating chamber and the second heating chamber, thereby providing It is configured to make heating and heat curing,
A planar heating element for promoting heating and curing curing of the concrete structure by radiant heat on each of the front surface of the first chamber forming panel portion facing the sidewall of the concrete structure and the front surface of the second chamber forming panel portion facing the ceiling of the concrete structure. Is configured to be installed,
A panel support frame installed inside the concrete structure, the first chamber forming panel portion and the second chamber forming panel portion respectively connected to the panel supporting frame, and the first chamber forming panel portion with respect to the concrete structure sidewall. And a plurality of gap adjusting means made of a hydraulic cylinder for adjusting a distance and adjusting a distance of the second chamber forming panel portion with respect to the ceiling of the concrete structure.
The hot air spray nozzle unit,
It is installed to penetrate each of the first chamber forming panel portion and the second chamber forming panel portion, the pin insertion passage formed in the rear end and the inside of the front end portion to be connected to the pin insertion passage is hot air to the concrete Hot air nozzle having a front injection passage for injecting toward the structure, and a side injection passage formed to be connected to the front injection passage to inject hot air inclined backward toward the first chamber forming panel portion and the second chamber forming panel portion. Body;
It is installed at the rear end of the hot air nozzle body, the hot air supply passage is formed to be connected to the pin insertion passage to provide hot air to the pin insertion passage, one side is installed to be connected to the hot air supply passage in the steam and hot air generator A hot air supply block having a hot air supply port for supplying hot air to the hot air supply passage;
An opening / closing pin inserted into the pin insertion passage to block or open a rear end of the front injection passage while moving forward and backward;
The flow rate is inserted into the hot air supply passage, and configured to move back and forth along the opening and closing pins, and adjust the opening and closing degree of the outlet of the hot air supply passage to adjust the flow rate of hot air supplied to the pin insertion passage through the hot air supply passage. Control pins;
And a control pin driving member connected to one side of the flow control pin in a rack-pinion manner to move the flow control pin forward or backward according to the rotation direction.
The steam and hot air generator,
An upper part is formed in an open tubular shape, the air inlet is formed on one side of the lower side, the water inlet is formed on the other side, the upper body is formed with a steam outlet connected by the steam injection nozzle unit and the steam transfer hose on one side;
A lid coupled to cover the open top of the device body and having a hot air outlet formed at the center thereof connected to the hot air spray nozzle unit by a hot air transfer hose;
Consists of a cylindrical shape is installed so as to be vertically disposed in the interior of the device body is formed so that a plurality of coil seating grooves formed in a circular ring shape along the inner circumference to be spaced apart a predetermined interval up and down, the air introduced through the bottom proceeds A heating member made of a ceramic material to generate hot hot air while discharging the generated hot air to the hot air outlet;
A coil-type heating wire installed to be inserted into the coil seating groove and seated therein and heating the heating member while being heated by an electric supply;
A fan motor installed inside the device main body and sucking outside air through the air inlet to supply air into the heating member;
A steam connecting the water inlet and the steam outlet to penetrate the heating member up and down and heated to a high temperature by the heating member to generate hot steam from water introduced through the water inlet and discharged to the steam outlet. Generating tube;
Spirally wound on the upper surface of the lid and one side is connected to the water storage tank, the other side is installed to be connected to the water inlet, to supply the water received in the water storage tank to the water inlet, through the hot air outlet A preheating tube which heat-exchanges with the lid heated by the discharged hot air and supplies the water to the water inlet while preheating the water to a predetermined temperature;
And a water transfer pump installed on a connection flow path connecting the water storage tank and the preheating pipe to transfer the water contained in the water storage tank to the preheating pipe.
The device body has a first cooling air inlet hole is formed, the outer peripheral surface of the heating member is connected to the coil seating groove and the second air to be supplied to the coil seating groove to the outside air introduced through the first cooling air inlet hole A cooling air inlet hole is formed, and a shutter member is configured to simultaneously open and close the first cooling air inlet hole and the second cooling air inlet hole while moving forward or backward according to driving of a cylinder module installed on the outside of the device body. , The first cooling air inlet hole and the second cooling air inlet hole are opened by the shutter member so that outside air flows through the first cooling air inlet hole and the first cooling air inlet hole. It is supplied to, characterized in that configured to prevent overheat damage to the heating wire by cooling the heating wire installed in the coil seating groove Winter concrete curing device.

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