KR101105095B1 - Electric curing apparatus and concrete curing system for out of use water and steam - Google Patents

Abstract

PURPOSE: A concrete curing system and an electronic curing apparatus without water and vapor are provided to eco-friendly implement a curing process with respect to concrete based on a wet air naturally generated from a curing chamber. CONSTITUTION: A heater unit(300) includes a heater body and a heater guiding pin. The heater body includes a heater inserting hole, fixing plates, and a bolt fastening hole. A heater is inserted into the heater inserting hole. The heater unit further includes a heater body internal guiding plate(3300), a heater body external plate(3200), and a hopper(3500). The outlet of a blower(100) is in connection with the sucking hole of the heater unit. A sucking temperature sensor(200) is arranged between the heater unit and the blower.

Description

Electric curing Apparatus and concrete curing system for out of use water and steam}

The present invention relates to a curing system and an electric curing device for curing various concrete block products such as interlocking, retaining walls, shores, vegetation blocks, and reinforcement soils, and concrete products molded using molds and molds by pouring concrete. In particular, the present invention relates to a concrete curing system and an electric curing device that uses only moisture contained in a cast or molded concrete product without supplying water and steam from the outside for curing the concrete.

The curing room usually uses sandwich panels, tents and other shielding materials to secure the curing room in a certain space and loads the product inside the shielded curing room. It is in air, ie wet air.

In the present invention, the wet air is sucked into a blower and passed through an electric curing device, gradually warmed at 70 ° C. initially, regenerated with an elevated heat source of 200 ° C. to 300 ° C., and re-supplied to the curing room, whereby the temperature in the curing room is increased and concrete. As the temperature of the product increases, the cement component and water of the product cause spontaneous hydration reaction, and the product promotes curing with the generation of heat of hydration.

The heat of hydration generated during the curing process is increased through the electric curing device of the present invention, and the temperature of the curing product is increased due to the continuous and repeated curing which supplies the heated heat-up and regenerated heat source back to the curing chamber. As the curing progresses and the curing progresses, the heat of hydration and saturated moisture discharged by the product are sucked into the electric curing device and regenerated from 200 ℃ to 300 ℃ to be re-supplied to the curing room, and the temperature of the product rises naturally. Reaction is more active, curing system and electric curing device using the virtuous cycle curing process to induce and promote curing of concrete products.

The process and method of curing using the curing system and the electric curing device will be described in detail as follows.

First of all, the concept of curing is to inhale the humid air naturally generated inside the curing room and to supply the regenerated heat source that is heated and regenerated through the electric curing device to the curing room repeatedly and continuously. In order to prevent rapid temperature change between the electric curing device and the product, curing is performed at intervals of sequential temperature and time of 70 ° C to 100 ° C in the first step, 150 ° C to 200 ° C in the second step, and 300 ° C to 300 ° C in the third step. When supplied to the room, the temperature of the curing room increases with the temperature of the curing room, and the product mixed with cement and water causes a hydration reaction by itself, and the curing of concrete products occurs. The product inside the nursing room through a curing process that raises the temperature of the curing room and the product through a series of repetitive and continuous cycles in which the hydration heat discharged from the curing process is sucked back into the electric curing device and re-heated and supplied. Cyclic curing system and electric curing to induce and promote the hydration reaction by water containing only this water to achieve the original purpose of curing the strength and increase the durability of concrete without supplying water and steam from the outside. Relates to a device.

There are dry products and wet products according to the types of products. The concrete products are classified into wet curing and dry curing according to the curing process and method. In addition, the conventional curing method is a wet curing by heating the water to generate steam by curing the heat and dry curing using the radiant heat using a heat radiator such as a pipe or a radiator, and dry curing using direct combustion heat of the burner, It can be classified into dry curing using electric energy and natural curing using natural environment without supplying heat source from the outside, and it is cured variously according to the type and purpose of concrete products.

However, among these curing methods, water is used as a fruit and heat is applied to generate wet steam and spray it directly to concrete products. Steam boilers and burners are used, and most of them use fossil fuels to burn their heat of combustion. During the combustion process, air pollutants are emitted and a considerable amount of water pollutants are produced by using steam.

In particular, curing using steam requires a lot of water to generate steam, and a large amount of state conversion energy is required to change the state of the water to steam by heating the water.

In wet curing, fuel is combusted to heat water with combustion heat to generate steam, which is used for curing, and in dry curing, the combustion heat is used directly, or steam is used as a heat radiator to obtain heat sources for curing. In the used curing, the steam supplied to the curing chamber according to the use of steam is liquefied together with the discharge of air pollutants, and the condensed water is condensed into the product or reacts with cement compounds and pigments and flows out into the curing chamber, leaving the factory. Not only is it a source of pollution, but a considerable amount of water resources are being consumed.

Therefore, in order to obtain the heat source necessary for curing, the concrete is prevented from being wasted due to the unnecessary supply of energy for changing the state of water to steam, and the concrete is not generated without causing the air pollution source without causing excessive pollution of water and groundwater resources. It is to achieve the purpose of curing and protect the global environment through eco-friendly and economical curing by using the curing system and the electric curing device that can be cured, that is, the curing system and the electric curing device that do not use water and steam.

In conventional wet curing and dry curing using steam, water is used as a fruit and water is heated to make steam to cure. In this process, since the state of water to steam must be converted and supplied to the heat source of curing, a large amount of energy must be supplied according to the state transition. In the present invention, as a curing system and an electric curing device to cure without using water and steam, the suction and circulation of the naturally occurring wet air in the curing chamber by virtuous cycle curing method without wasting unnecessary energy due to the state conversion from water to steam and This is to prevent unnecessary waste of energy due to steam curing, reduce curing costs, and economically cure by supplying only the necessary heat source necessary for curing.

Most burners and steam boilers that use fossil fuels generate steam by directly using the combustion heat generated during the combustion of fuel or by heating the water with the combustion heat, and the exhaust gases generated during the combustion process are emitted into the atmosphere, causing air pollution. In the electric curing device of the present invention, it is for environmentally friendly curing without generating air environmental pollution without discharging the combustion gas generated during the curing process using existing fossil fuel.

In wet curing or dry curing using existing steam, water must be supplied to use steam, and the supply of water leads to waste and exhaustion of groundwater resources. The present invention is a circulatory curing system that does not use water and steam, which is curing using the moisture contained in the curing room product. That is, the suction air is heated and heated through an electrical curing device, and a regenerative heat source is supplied to the curing room, Hydration heat and water by hydration reaction are sucked and warmed again, and a series of curing processes that are supplied by suction recovery and warming again are cured by repeated and continuous curing process, that is, by virtuous cycle curing method. By curing the hydration by self hydration reaction and the re-heated heat source, the water and steam required for curing are cured without supplying from the outside compared to the existing steam curing, thereby preventing the waste of groundwater resources. To protect groundwater resources and cure eco-friendly The.

In wet curing of steam, condensed water is always generated inside the curing chamber due to the use of excessive saturated steam, and the condensate reacts with the cement component of the concrete product and its compound or pigment compound. And it is discharged outside the curing room, causing water pollution. The present invention does not generate unnecessary condensed water in the curing chamber by curing without supplying unnecessary water and steam for curing. Therefore, it is to make curing while avoiding the discharge of unnecessary water pollution source.

In the present invention, the concrete product formed by the combination of cement, aggregate, and water inhales and warms the humid air in the curing room using the characteristic environment existing in the curing room in the form of air, that is, moisture, that is naturally evaporated or discharged. In order to reduce curing cost and to use efficiently and economically, it is possible to cure with the minimum curing heat source by supplying heat source necessary for curing by the repetitive and continuous method of supplying it by virtuous cycle curing method and electric curing device. to be.

As mentioned above, the fossil fuel is used to heat water and generate steam to cure using the heat source of the steam, or the heat of combustion of the fuel as the heat source for curing, causing air pollution and water environmental pollution, and excessive water to cure. By using and steam causes groundwater resources to be wasted and cured in an uneconomical and inefficient way, in the present invention, water pollution and air pollution are fundamentally utilized by using a virtuous cycle curing system and an electric curing device that do not require water and steam. It is to cure economically and efficiently while blocking and restraining the waste of groundwater resources.

As shown in FIG. 1, the suction pipe 900 and the suction control valve 901 are provided with the air and moisture sucked from the curing chamber, that is, the evaporated water in the curing chamber and the air inside the curing chamber contained in the product 1000 of the curing chamber 1100. The wet air of the curing room, which is sucked into the blower 100 and supplied to the electric curing device 300, is heated while passing through the electric curing device 300, regenerated into an elevated heat source, and supplied to the curing room 1100 for curing. will be. At this time, the temperature supplied to the curing room is primarily 70 ° C. to 100 ° C., secondly 150 ° C. to 200 ° C., and thirdly 220 ° C. to 300 ° C., in order to prevent the temperature of the curing room from rising or changing rapidly. If the heating step by step until the temperature of the curing room 1100 is gradually increased and the temperature of the product 1000 is also naturally increased, the product mixed with cement and water occurs the hydration reaction itself and the heat of hydration generated during the hydration reaction Naturally, the product is sucked into the blower 100 through the suction pipe 900 together with the moisture generated in the discharge process, regenerated by the heated heat source again through the heater device 300, and supplied to the curing chamber 1100 again. The temperature of the concrete is continuously raised so that the concrete product (1000) promotes curing along with the continuous hydration reaction. By using a continuous and repetitive virtuous cycle curing method to induce and promote this hydration reaction, the regenerated heat source is again supplied to the curing chamber 1100 through the heater device 300 to cure the cement product (1000) together with the supply heat source. ) Is an electric curing device 300 and a virtuous cycle curing system that promotes curing by reusing hydration heat emitted by itself.

Therefore, in order to continuously cure the product in the curing room, the temperature required for the hydration reaction must be supplied. The temperature in the curing room is maintained at 30 ° C to 40 ° C for dry products, and for semi-dry products at 40 ° C to 50 ° C. If the wet product is maintained at 60 ℃ to 70 ℃, the concrete product spontaneously hydrates and discharges the heat of hydration, and reuses the heat of hydration in the curing room, and warms it again through the electric curing device 300 to regenerate the heat source. It supplies the curing room to promote the hydration reaction to cure the product.

That is, according to the type of the product 1000, the temperature supplied to the curing chamber 1100 is initially supplied from 70 ° C to 100 ° C and gradually raised to be heated and regenerated to a temperature of 200 ° C to 300 ° C to be cured. The temperature of the room is gradually increased, and naturally, the product is hydrated by the temperature rise and the heat of hydration is released, so that the temperature inside the curing room is continuously maintained. In this continuous virtuous cycle, the water generated from the product is saturated in the curing room, and the product is continuously hydrated in the process of hydrating heat and being absorbed or absorbed by the product depending on the temperature of the curing room. Curing is promoted because of this. Therefore, if the suction of the humid air of the curing room in a virtuous cycle curing method and heated and regenerated through the electrical curing device 300 to supply the temperature of the curing chamber 1100 and the product 1000 in the curing chamber is the desired hydration reaction temperature By reaching this, you will be able to continue to cure. Therefore, it is possible to induce and promote the hydration reaction with only the moisture contained in the product 1000 without receiving water and steam from the outside, thereby achieving the original purpose of durability and early strength of the product, which is curing. Eco-friendly and economical curing can be achieved without causing air pollution and water pollution and without wasting unnecessary groundwater resources.

The present invention is an eco-friendly and economical curing system and electric curing device that can achieve the original purpose of curing without causing air pollution and water pollution and waste of unnecessary groundwater resources.

As described above, in the present invention, an existing fossil is used to induce and promote a hydration reaction in curing by inducing an artificial process of curing in order to make a durable concrete product having sufficient binding strength and strength. It takes away from the steam using fuel and the heat of combustion and supplies water and steam from the outside without supplying water and steam from the outside, and circulates to the electric curing device and system using moisture generated naturally from the air and the product, that is, wet air. It relates to eco-friendly and economical curing to accelerate the hydration reaction of the product by heating the temperature.

In the existing concrete curing, most of them were used for wet curing and dry curing using steam or direct combustion heat. In steam curing, the fossil fuel is burned and the water is heated and evaporated using the heat of combustion. Thus, the fossil fuel emits air pollutants generated during the combustion process. In wet curing where water is directly supplied, steam supplied to the curing chamber condenses on concrete products inside the curing chamber or is generated as condensate and leaks to the bottom of the curing chamber. The effluent mixed with the compound of is discharged out of the factory outside the curing room, which is the cause of water pollution.

In the present invention, in order to solve and prevent these problems, by using the electric curing device and the curing system only by the moisture contained in the concrete product itself by using a curing system without the supply of water and steam from the outside unnecessary water resources due to steam curing In addition to preventing the waste of water, it is possible not only to prevent the generation of water pollution sources due to the use of excessive water, but also to prevent the emission of air pollutants. In addition, steam curing requires state position conversion energy in order to convert water into steam, but by supplying only a heat source necessary for the hydration reaction using a curing system and an electric curing apparatus that do not use water and steam of the present invention, the product itself hydration reaction. It is possible to cure without causing unnecessary waste of energy by promoting curing by.

In particular, it is possible to achieve the purpose of curing and production of uniform products without using water, and excessive moisture from steam use condenses on the steel structure of the curing room to increase corrosion or exhaust by direct combustion heat. It is economical because it can prevent the phenomenon of shortening the service life by promoting oxidation corrosion of mold or mold by gas.

In addition, it can protect water resources, prevent unnecessary waste of energy, and prevent water pollution and air pollutants from being released. It is an electric curing device.

1 is a 1: 1 control diagram of an electric curing device and a virtuous cycle curing system in a single curing room.
2 is a control diagram of the electric curing device and the virtuous cycle curing system in multiple curing rooms
3 is a control diagram of the electric curing device and the virtuous cycle curing system in bridge pier curing
Figure 4 is an overall assembly of the electric curing device
5 is a detailed view of the heater device in the electric curing device
Figure 6 is an overall assembly view of the heater device in the electric curing device
In the drawings, the names of the parts are as follows.
10; electric curing device mounting table
100; blower
150; electric curing device Hurenji 151; flange bolt hole
200; suction temperature sensor
300; heater device
301; Heater body, 302: Heater guide pin 303: Heater insertion hole 304; Bolt tightening hole
305: Insulated ceramic 306: Heater terminal tightening nut 307; Heater body cover tightening bolt
310; Heater body body side fixing plate 320; Heater body body side fixing plate
330 Heater body outlet side fixing plate
500; External caching Air intake 510; External caching
700; discharge temperature sensor
800; discharge supply pipe 801; discharge control valve
900; suction pipe 901; suction control valve 902; heat dissipation suction control valve 903; heat dissipation suction pipe
1000; Cured Product 1001; Tents
1100; curing room A, B, C, D 1101; curing room temperature sensor 1102: curing room humidity sensor
1500; Curing System Control Unit
2300; Heater body outlet bending reducing hopper
3000; heater
3001; heater device body cover 3003; heater device body cover heater insertion hole 3004: heater body cover outer border fixing plate 3200; heater device body outer plate 3201; heater device body inner guide plate fixing support rod 3300: heater device body inner guide plate 3301; Heater Body Outer Plate Fixed Support Rod 3500; Bending Reducing Hopper

As shown in FIG. 1, the curing system and the electric curing apparatus that do not use water and steam of the present invention include a heater device 300 including a blower 100 and a heater 3000, and a suction pipe 900. Suction control valve 901 External air suction control valve 906 Discharge control valve 905 and discharge tube 800 Discharge control valve 801 and heat dissipation suction control valve 902 Consists of heat dissipation suction tube 903 and controls the curing system. The temperature control unit, the time control unit and the power control unit are configured to cure according to the temperature, time, and humidity according to the product to be cured according to the curing process and method. The curing system is controlled by the curing system 1500 and starts the electric curing device. do.

In curing through the curing system and the electric curing device, a heater 3000 is inserted into the heater device 300 for supplying a heat source as shown in FIG. 6 and fastened, and the heater is repaired and replaced by damage to the heater 3000. Heater device 300 by fastening the heater device body 301 and the heater device body cover 3001 of the two-stage separate assembly type structure shown in FIG. ) And divide the multiple heaters 3000 by unit configuration in order to control step by step according to the setting temperature of the curing room, and separate the units of the heater into 3 units and wire them according to the voltage to the power control unit of the curing system control unit 1500. Connect and the outside of the heater device 300 to insulate with insulation and the outer caching 510 to disassemble and assemble.

In particular, as shown in FIGS. 5 and 6, the heater device 300 absorbs the heat radiated from the upper and lower side portions of the curing chamber sucked into the blower 100 by the heater device 300. In order to supply the inside and to suppress the phenomenon that the heat of the heated heater 3000 heats up or flows back to the blower side, the heater device body inner guide plate 3300 is installed, and the heater device 300 is placed outside the top and bottom outside. Heat guide pins to form a 3-pass space in the heater device 300 to absorb the heat dissipated to the outside while being supplied into the heater device 300 and to maintain an angle of 30 to 45 degrees in the exit direction on the upper and lower sides of the heater device ( 302 is attached to direct the flow of air flowing along the upper and lower surface of the inside of the heater device 300 to the plurality of heater centers, thereby effectively curing the amount of heat emitted from the heater 3000 while curing. In order to configure the structure to be discharged to the heater unit 301 and to efficiently use the heat dissipation generated from the heater connection portion protruding from the left and right sides outside the heater as shown in Fig. 100) and the heat dissipation suction pipe (903) to the heat dissipation suction control valve 902 to install a heat dissipation suction control valve 902 to detect the heat dissipation temperature to control the suction amount of the heater unit body together with the humid air of the curing room sucked into the suction pipe (900) Efficiently inhale and use heat radiation.

When the heater device 300 to which the heater 3000 is fastened is completed as shown in FIG. 6, as illustrated in FIG. 4, a blower 100 is attached to an inlet of the heater device 300, and a supply pipe is formed at an outlet of the heater device 300. 800 is connected to the suction pipe 900 for suctioning the humid air in the curing chamber to the inside of the curing chamber 1100, the suction pipe 900 and the suction control valve 901 outside air suction control valve 906 and the discharge control valve 905 is configured to be connected to the suction port of the blower 100 side to suck the humid air of the curing chamber 1100 into the blower 100 and to supply the inside of the curing chamber to the discharge supply pipe 800 through the heater device 300. An integrated vicyclic electrocuring device and system for the same are configured as shown in FIG.

As shown in Figure 1, the humid air of the curing chamber is suction-circulated to the blower, heated through the heater device 300, and regenerated as an elevated heat source and supplied to the curing chamber, thereby increasing the temperature of the curing chamber and leading to an increase in the temperature of the product. The voluntary hydration of cement and water takes place, resulting in the curing process that results in the binding and durability of the product. In other words, the temperature of the curing room increases during a series of continuous and repeated curing processes such as suction circulation, heating, and supply curing. The temperature of the product rises to induce and promote curing through the voluntary hydration reaction of the product to perform the curing and curing using a virtuous cycle curing method that can cure without supplying water and steam from the outside.

In order to cure using an electric curing device, the curing system controller 1500 is configured, and a power controller, a temperature controller, and a time controller are configured to control the overall curing process according to the temperature and curing time of the curing room.

The power control unit for controlling the power of the blower 100 and the electric curing device is connected to the temperature control unit by installing a temperature sensor in the curing room 1100 so as to sense the temperature in the curing room and control the power of the electric curing device in parallel. At the outlet of the heater device 300, the wet air of the curing room sucked to the suction port side of the blower 100 passes through the electric heater device 300, and then is supplied to the discharge port side to detect and control the temperature of the wet air supplied to the curing room. The temperature sensor 700 is attached and the suction temperature sensor 200 is attached between the blower 100 and the heater device 300 inlet to detect the temperature of the wet air sucked in the nursing room and the temperature of the heater device 300 flowing back. In addition, the temperature control unit is configured to enable pre-purging and post-purging of the blower 100 in association with the power control unit.

Looking at the power control unit attached to the main circuit breaker for the power inlet or interruption, install an earth leakage breaker and heater in order according to the temperature of the curing room set in the temperature control unit to control the heater 3000 configured for each unit of the electric curing device In order to prevent the phenomenon in which the hydration reaction of the product 1000 occurs suddenly by sequentially heating the supply temperature by heating the 3000 and gradually promote the curing, the contactor is configured to contact the heater to generate heat. It is necessary to set the temperature in the curing room by setting the first set temperature, the second set temperature, and the third set temperature in order to cure the product according to the curing purpose of the product to be cured by the temperature controller. To operate by setting the product for each product. In order to prevent heat and damage to a part of the heater 3000, the magnetic contactor is attached step by step so that there is no problem in the power supply of the entire heater 3000. 3000 is configured to control and the heater 3000 for each component unit constituting the heater device 300 is each curing room (1100) set for each step configured by the temperature control unit and curing room temperature controller of the system In parallel with the set temperature, the heater 3000 is separated and connected for each structural unit so that the magnetic contactor can be contacted and controlled. In addition, when some heaters in the heaters 3000 configured for each unit are damaged, the damaged heaters of the heater device 300 to prevent the operation of the entire curing system and the electric curing device and to maintain the temperature of the curing room continuously. In order to cut off and control the power of the 3000, a circuit breaker is installed by separating the respective units of the heater 3000.

Looking at the process of starting and curing the electric curing device using the curing system control unit 1500 as follows.

First, when power is supplied, the suction control valve 901 of each curing room is opened. In the double curing room of FIG. 2, the blower 100 is started after the suction control valve 901 and the discharge control valve 801 are linked to each other, and the blower 100 is started, and then the pre-purge is performed for a time set by the time controller. While the process of inhaling and circulating the humid air inside the curing chamber 1100 continues and the set time passes, the magnetic contactor is contacted by the power control unit to supply power to the heater 3000, and comprises three steps of the temperature control unit and the time control unit. Each heater 3000 of the heating unit by the primary contactor in contact with the primary set temperature according to the instructions or set temperature of each step set in the thermostat to heat the heater unit 3000 of the heater unit 300 Supply the heat source to the curing room 1000 to increase the temperature of the curing room 1100 and to prevent overheating and load of the instantaneous heater device 300 The time control unit is configured to contact the secondary contactor by the secondary set temperature of the raw temperature controller, and after the preset time elapses after the secondary contactor contacts, the third contactor contacts the heater device 300 of the electric curing apparatus. Sequential warming of the inhaled nursing room air is supplied to the curing room as a regenerated heat source to induce and promote a hydration reaction to proceed with curing.

According to the temperature of the curing room set for each stage, each magnetic contactor reaching the curing target temperature of 3 stages is blocked and controlled. When the curing temperature set to the highest curing target temperature is reached, all the magnetic contactors are blocked and all the heaters 3000 The supply of power is stopped. At this time, the blower 100 continues the latent heat remaining in the heater device 300 and ends after performing a post purge by the set time controller for a predetermined time. After the blower 100 is turned off and curing is completed, internal latent heat remaining inside the curing apparatus 300 is generated or if the heat is reversed to the blower 1000 so that the motor and axial flow of the blower 100 may be damaged. When the temperature reaches 40 ° C. to 70 ° C. with the suction temperature control sensor 200 between the heater device 300 and the blower 100, the blower is started for a set time to discharge the backflowed air. To prevent overheating and damage to the blower 100.

When curing is performed by the set temperature of the temperature controller and the heater 3000 is heated by the magnetic contactor according to the temperature set for each step, and the temperature of the curing chamber 1100 reaches the final set temperature, the blower 100 is post-purged. After executing the curing is finished and enters the standby state and again the temperature of the curing room (1100) is lowered below the set temperature for each step, the blower (100) is activated and circulates the humid air of the curing room for a set time and set After a period of time, each of the magnetic contactors is sequentially contacted by the temperature controller of the temperature controller. The heated and regenerated heat source is heated to the curing chamber 1100 through the heater device 300 to hydrate the product 1000. Continued induction of the reaction promotes curing.

The curing system control unit may control the temperature setting of the curing room 1100 and attach a time timer to terminate the system process of curing separately from the curing temperature when a certain curing time has elapsed by the time set with the temperature control unit. It is configured to be controlled by the curing time, and the temperature control unit is configured to be constrained by the time control unit, it is configured in parallel with the 24-hour control unit that can be produced during the day and curing as time curing at night as necessary.

There are various kinds of concrete products to be cured, so curing only by temperature control depends on the curing quality or economic effect. If curing products are cured by curing temperature control and the products to be cured can be cured with time control, Curing is controlled through the control, and the curing time necessary for producing the product during the daytime and curing using the night time can be started and finished by night setting without time constraints. The curing system control unit 1500 is configured to cure an optimal product by curing with a plurality of control systems.

Through the time control, temperature control, and power control set by the curing system, the blower 100 is started and the suction air of the curing chamber is supplied to the curing chamber through the electrical curing apparatus 300, and the temperature rises inside the curing chamber and the product. By the temperature rise of 1000, the product discharges the heat of hydration along with the hydration reaction, and the discharged heat of hydration and wet air of the curing room are sucked back to the inlet side of the blower 100 and supplied to the heat source that has been elevated again through the heater device 300. Hydration reaction is more actively and continuously virtuous cycle curing is realized and when the temperature of the curing chamber (1100) by the supply heat source and hydration heat reaches the set curing temperature and the curing is finished, the blower 100 is started for a set time post The purge and electrical curing system device enters the standby state.

The discharge part temperature sensor 700 of the electric curing device detects the generated temperature and the discharge port temperature of the current heater device 300 and reaches a set temperature to prevent overload and overheating due to the temperature rise of the heater device 300. The power supply to the magnetic contactor in each step and the power supply to the heater 3000 are cut off and an alarm is issued. At this time, the blower 100 continuously performs post purging for a time set by the timer of the time control unit to perform a heater purge ( After discharging the latent heat of 300) and terminates, and also attached an emergency cutoff switch to cut off the power supplied to the curing device 300, and the blower 300 is supplied to the heater unit when starting is stopped due to overload All power to the contactor is not supplied and activates the alarm.

In curing, it is not one-to-one curing between the curing system, the electric curing device, and the curing room, and the curing targets are different. In this case, as shown in FIG. 2, a separate discharge supply pipe 800 is formed in the main supply pipe supplied from the discharge part of the electric curing apparatus 300 to the curing chamber, and the outlet part of the separate discharge supply pipe 800 for each of the curing chambers A, B, C, and D is discharged. Each discharge control valve 801 is installed in the air supply unit to supply the regenerated heat source that has passed through the heater device 300 to the lower end of the curing chamber, and an inlet is formed at the upper end of the curing chamber, and a suction pipe 900 is installed from the inlet. Connect to the suction port on the (100) side.

In the case of the suction pipe 900, if the multiple double curing room, as shown in Figure 2 to create a separate suction pipe 900, the suction pipe is installed as the suction port of each curing room A, B, C, D and curing of each A, B, C, D A suction control valve 901 is installed at the inlet of the chamber suction pipe, and the suction control valve 901 and the discharge control valve 801 of the curing chamber suction pipe 900 and the discharge pipe 800 of each of A, B, C, and D are connected to each other. After the discharge control valve 801 is opened, the suction control valve 901 of the suction pipe is opened and the power is supplied to the blower 100 to suck the humid air from the curing chamber to heat the heater 3000 of the electric curing apparatus. The humid air of the curing room heated and sucked by the blower 100 is supplied to the curing room as a heated and regenerated heat source through the heater device 300 so that the product undergoes spontaneous hydration reaction by the temperature rise, and the curing is accompanied by the generation of hydration heat. Is promoted. In this state of curing and operation of the system device, the power supply to the blower and the heater is not supplied when any one of the suction side suction control valve 901 and the discharge side discharge control valve 801 is closed. The valve can be opened and closed manually, and by adjusting the opening and closing angle of the control valve, the amount of wet air in the nursing room to be sucked is controlled to adjust the temperature required for curing to the intake air ratio.

Therefore, the initial wet air in which the wet air in the curing room is sucked into the blower 100 through the suction pipe 900 is heated up after passing through the electric curing system, and is changed to the temperature of the regenerated heat source. If the temperature is supplied to the inside of the curing room by making the supply temperature around 160 ℃ and around the third 250 ℃, the temperature inside the curing room is increased by regenerated heat, and the product naturally rises by the elevated temperature, and the concrete itself is contained. The cement component and the water which are used cause the hydration reaction by themselves. Then, the exothermic heat of hydration is generated and the concrete products are cured and promoted during the hydration reaction. Saturated water generated in the curing chamber during the discharge of the hydration heat is sucked back into the suction port of the blower 100 through the suction pipe 900 and regenerated and heated again through the electric heater device 300 to be supplied to the curing room. Curing with the virtuous cycle of curing method and curing system such as continuous and repetitive inhalation, heating and supplying, induces and promotes the hydration reaction of the product with only the moisture contained in the concrete product (1100) due to the temperature rise in the curing room. It can be cured. In addition, the saturated moisture generated during the discharge of the hydration heat generated in the curing process is recovered to the suction pipe again without being discharged to the outside or outflow, and made into a heated and regenerated heat source that is heated through the heating device 300 of the electric device, thereby separately. Even without supplying water or supplying water, the product 1000 generates a hydration reaction by itself and discharges hydration heat. Saturated wet air by the hydration heat in the curing chamber is sucked into the blower 100 again and is heated by the heater device 300. By continuously supplying and circulating the heated and regenerated heat source through the virtuous cycle of curing and supplying it to the curing room, it supplies heat source necessary for the hydration reaction to promote curing and the curing room always maintains uniform and constant temperature. It is possible to cure the uniform product and the heated humid air of the curing room. By continually circulating and maintaining, inducing and facilitating repetitive hydration reactions, condensation water condenses on the surface of the product due to supersaturated vapors appearing in the existing steam curing process. Curing can also be prevented.

In the case of curing the A curing room in the multiple dressing room, the suction control valve 901 and the discharge control valve 801 of the A curing room of FIG. 2 are opened and sucked by the blower 100 by the electric curing system of the present invention. The humid air inside the curing room is heated up through the heater device 300, and the regenerated heat source is supplied to the curing room again to increase the temperature of the curing room and reaches the target curing temperature set by the temperature control unit and the time control unit to the heater 3000. After the power supply is stopped and the blower 100 post-purges the latent heat of the heater device 300, the curing is terminated and the curing enters the standby state.

In the case of curing B curing room, if the automatic 24 hour timer switch is contacted by the B curing room time control unit set in the curing system control device or the curing system is operated by operating a manual switch, the suction control valve of the curing room A of FIG. ) And the discharge control valve 801 is closed, the discharge control valve 801 of the B curing chamber and the B curing chamber suction control valve 901 of the suction pipe 900 are opened, and suction the wet air of the B curing chamber to the blower 100. When the heating device 300 is heated up and regenerated to be regenerated heat source and supplied to the B curing room, the hydration reaction is induced and promoted by increasing the temperature of the curing room, and the curing is expressed. When the curing process is terminated by the set curing temperature of the temperature control unit of the curing room or by the set time of the control unit of the curing unit, the blower 100 performs post purging and enters the standby state. When the curing system starts, the suction control valve 901 and the discharge control valve 801 of the curing room B are closed, and the curing of the curing room B is completely terminated, the intake control valve and the discharge control valve of the curing room C are opened, Curing proceeds. Then, D curing room can continue to cure sequentially through the opening and closing of the inlet and discharge control valves of the D curing room. As shown in FIG. 1 or FIG. , 1; 1 can be cured by the curing system, or as shown in Figure 2, or can be cured in a multi- or double curing room individually or sequentially A, B, C, D in order to cure by manual control of the entire curing room It is a curing system that can cure multiple curing room products with one electric curing device.

Therefore, the curing system and the electric curing device of the present invention can be cured without using water and steam, thereby preventing unnecessary waste of water resources and preventing further generation of air pollution and water pollution sources. You can cure.

When the heater 3000 is inserted into the heater device body 301 having a structure capable of assembling and disassembling the heater 3000 as shown in FIG. 5, the heater device 300 as shown in FIG. 6 is completed and the heater device as shown in FIG. 4. The blower 100 is attached to the inlet side, and a supply pipe is configured on the outlet side of the heater device 300. As shown in FIG. 1, a connection pipe having a suction pipe 900 for suctioning the wet air of the curing chamber 1100, a suction control valve 901, and an external air suction control valve 906 is connected to the suction side of the blower 100, and a heat radiation suction pipe A suction temperature sensor 200 and a heater connecting the 903 and the heat radiation suction control valve 902 to the suction pipe 900 and detecting the latent heat of the curing device between the heater device 300 and the blower 100 of the electric curing device. Attaching the outlet temperature sensor 700 to the outlet supply pipe 800 of the device 300 makes an integral electric curing device. In the curing chamber 1100, moisture evaporated or released from the product and indoor air are sucked into the air inlet of the blower, and the temperature required for curing is sequentially supplied through the heater device 300 of the electrical curing apparatus. The temperature is increased and the temperature of the product 1000 is also increased to cause the concrete product to hydrate by itself to cure, and the heat of hydration and moisture generated in the curing chamber 1100 together with the air in the curing chamber are returned to the blower 100. By suctioning and supplying at an elevated temperature of 200 ° C to 300 ° C through an electric curing device, the moisture released together with the heat of hydration by the hydration reaction of the product is sucked together with the heat of hydration and supplied to the curing room again, thereby maintaining a continuous and continuous hydration reaction. Curing is promoted.

Depending on the product, it is necessary to cure by varying the temperature of the curing room. For dry products with small moisture content, 30 ℃ to 40 ℃ for semi-dry products, 40 ℃ to 50 ℃ for semi-dry products, and 60 ℃ to 70 ℃ for wet products with high moisture content It is maintained at ℃ and the suction control valve 901 of the suction pipe (900), the outside air discharge control valve 905, the suction control valve 906 is controlled to control the circulation of the curing room. The wet method induces the hydration reaction of the product by varying the circulation ratio according to the conditions of temperature and humidity of the curing room or by controlling the temperature in the curing room by controlling the set temperature of curing in one stage, two stages and three stages of the electrical curing apparatus. By using a series of virtuous cycle methods to achieve the purpose of curing by inhaling and heating the humid air of the curing room with the electric curing device, the regenerated heat source is continuously maintained using the curing system and the electric curing device. Supplying to a curing to induce and accelerate the hydration of the product.

Claims (10)

Heater 3000 inserts and assembles and separates the heater insertion hole 303 and the heater device body inlet side fixing plate 310, the heater device body center side fixing plate 320, and the heater device body outlet side fixing plate 330 and bolts. A heater device body 301 constituting a tightening hole 304;
A heater guide pin 302 having an angle of 30 degrees to 45 degrees in the exit direction in the upper and lower surface portions of the heater device body 301;
Heater body inner guide plate 3300, guide plate support rod 3201 and heater device body outer plate support rod which induces air inflow and flow to the outside of the heater device body 301 and the air flow constitutes a three-pass space It supports and seals the outer end of the heater device body 301 upper and lower outlets with the heater device body outer plate 3200 and connected to the reducing hopper 3500 bent to the blower 100 outlet side to the heater device body 301 inside the heater. And the heater device 300, characterized in that the fastening by injecting (3000).
The outlet of the heater device 300 is connected to the outlet of the blower 100 by the flange 150, and a suction temperature sensor 200 is provided between the heater device 300 and the blower 100 and the outlet supply pipe of the outlet side ( A heater device 300 having a discharge control valve 801 attached thereto;
Outside air intake control valve 906 at the inlet of the blower 100 for sucking the heat of the heater device 300 to the air inlet 500 and the heat intake pipe 903 of the outer casing 501. Electric curing device, characterized in that configured. The insulating ceramic 305 and the heater 3000 are inserted into the heater insertion hole 303 of the heater device body 301, and the insulating ceramic 305 is inserted into the heater insertion hole 3003 of the heater body cover 3001. And fasten with the heater terminal tightening nut (306), and close the heater body body (301) side fixing plate with the heater body cover outer edge fixing plate (3004), and bolt tightening hole (304) with the heater device body cover fixing tightening bolt (307). Electron curing device for passing the flow of air using only the heater device 300, characterized in that the structure is configured to assemble and separate the heater (3000) by fastening to). The bending reducing hopper 3500 to which the suction temperature sensor 200 is attached is connected to the inlet of the heater body 301, and the heater body 301 exit bending reducing hopper to the outlet of the heater body 301. An electric hot air fan configured to supply a supply pipe 800 to which the discharge temperature sensor 700 is attached, and attach the discharge temperature sensor 700 to the heater device 300, and to which the blower 100 is attached;
The suction pipe 900, the suction control valve 901, the discharge control valve 905, and the outside air suction control valve 906, which are introduced into the curing chamber 1000, are connected to the suction port of the blower 100 and supplied to the suction port of the electric hot air blower. An electric curing apparatus, characterized by injecting the 800 into a sealed or shielded curing chamber 1100 and providing a curing temperature sensor 1101 and a curing humidity sensor 1102 to inhale the humid air of the curing chamber and to circulate curing. delete delete delete delete delete delete delete

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