JP2006143531A - Curing apparatus for hardened body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a curing apparatus for improving properties of a hardened body using a modification treating body and the curing apparatus for the hardened body in which the flow-out of the modification treating body is prevented at a low cost, workers attending to the carry-in and -out work are needless to work in the modification treating body atmosphere and the loss of the modification treating body is reduced. <P>SOLUTION: The curing apparatus for the hardened body is provided with a vessel 2 housing the hardened body A and tightly closed and the modification treating body C for improving the property of the hardened body A is filled in the vessel 2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a curing device for a cured body that can be cured with a modified body such as carbon dioxide gas while improving the properties of the cured body such as a concrete product or a mortar product.

  Conventionally, as a method for curing concrete products, there is steam curing in which concrete products are cured under high temperature steam. Steam curing is one of the accelerated curing of concrete. It can mainly increase the initial strength in normal pressure steam curing at normal pressure of 100 ° C or less, and the initial strength can be increased in high pressure high temperature steam curing (autoclave curing). And excellent dimensional stability and corrosion resistance can be obtained. Steam curing is performed by placing a concrete product in a curing chamber and supplying high-temperature steam into the curing chamber (see, for example, Patent Document 1).

In recent years, carbonation curing has been proposed in which concrete products are cured in a carbon dioxide atmosphere. According to this method, free lime [Ca (OH) ₂ ] produced by the reaction between cement and water is brought into contact with carbon dioxide gas [CO ₂ ] to produce calcium carbonate [CaCO ₃ ] and has a volume. Inflate. When the volume expands, the voids in the matrix are filled and densified, so that the water absorption can be reduced and the strength can be increased (for example, see Patent Document 2).
Japanese Patent Laid-Open No. 2003-21433 JP-A-5-24952

However, although the above-described conventional steam curing can increase the initial strength, there is a problem that the strength expressed after the curing cannot be increased. Moreover, since a lot of minute voids are formed in the concrete product, there is a problem that moisture and gas can permeate when pressure is applied for a long time.
In addition, in the above-mentioned carbonation curing, high-concentration carbon dioxide gas adversely affects the human body and the global environment. There is a problem that it is necessary to ensure, and considerable cost is required to ensure safety. In steam curing, an entrance is provided in the curing room, and while steam curing is performed, workers carry out concrete products after the curing period and carry new concrete products into the curing room. It is not preferable that the worker enters the curing room and puts in and out the concrete product because it is dangerous work. Moreover, since the carbon dioxide in the curing chamber flows out each time the entrance is opened, there is a problem that the loss of carbon dioxide increases.

  The present invention has been made in consideration of the above-described conventional problems, and provides a curing device capable of improving the properties of a cured product such as a concrete product by a modified treatment product such as carbon dioxide gas, and at a low cost. Provided is a curing body curing device that can prevent outflow of a reforming treatment body, and that an operator who carries in and out the work does not work in the reforming treatment body, and the loss amount of the reforming treatment body is small. The purpose is that.

The curing body curing device according to the present invention is provided with a container in which the cured body is stored and sealed, and the container is filled with a modified body that improves the properties of the cured body. It is said.
Due to such characteristics, the cured body reacts with the modified body in a sealed container, so there is no need to seal the space in which the container is placed, and curing can be performed even if other cured bodies are carried in and out. The reforming body in the container inside does not flow out.

Moreover, it is preferable that the hardening | curing body curing apparatus which concerns on this invention is arrange | positioned so that a container can move.
Thus, the cured body can be transferred while being cured in the modified body atmosphere.

Moreover, it is preferable that the curing device for curing body according to the present invention is provided with supply means for supplying the modified body into the container.
As a result, an appropriate amount of the modified body can be filled in the container, and the modified body concentration in the container can be maintained at a concentration suitable for curing the cured body.

In the curing body curing device according to the present invention, the container is preferably provided with a concentration detection means for detecting the concentration of the modified body in the container.
As a result, it is possible to manage the concentration of the modified body in the container while maintaining the hermeticity of the container.

Moreover, it is preferable that the curing body curing device according to the present invention includes a humidity adjusting means for adjusting the humidity in the container.
This makes it possible to maintain a humidity suitable for improving the properties of the cured body with the modified body.

Moreover, it is preferable that the curing device for curing body according to the present invention is provided with heating means for increasing the temperature in the container.
Thereby, it can heat to the temperature suitable for improving the property of a hardening body by a modification process body.

Moreover, it is preferable that the curing body curing device according to the present invention is provided with a pressurizing means for applying pressure in the container.
As a result, pressure is applied to the container, and the reaction between the modified body and the cured body is promoted.

In the curing apparatus for curing a cured body according to the present invention, the modified body is preferably made of carbon dioxide or carbonated water, and the cured body is preferably made of a cement-based curable substance.
As a result, the surface portion of the cured body made of a cement-based curable substance is carbonated and densified, and the strength is also increased.

The curing body curing device according to the present invention is preferably provided with an exhaust gas supply means for supplying exhaust gas, and the reforming body in the container preferably contains exhaust gas.
As a result, exhaust gas that affects the environment can be efficiently reused, and energy can be saved.

  According to the curing apparatus for curing a cured body according to the present invention, a reformed body is filled in a sealed container containing the cured body, and the cured body and the modified body are sealed in the sealed container. Since it reacts, it is not necessary to seal the space in which the container is placed, and the outflow of the reforming treatment body can be prevented at low cost. In addition, since the modified treatment body in the curing container does not flow out even if other hardened bodies are carried in and out, workers carry out the work of carrying out the hardened bodies in a space where there is no modified treatment body. It is also possible to reduce the amount of loss of the modified body filled in the container being cured.

  Hereinafter, the first and second embodiments of the curing device curing apparatus according to the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 1 is a schematic diagram showing a curing device 1 according to the present invention. As shown in FIG. 1, a curing device 1 is disposed in a curing room R, and a container 2 in which a concrete product (hardened body) A is stored, and carbon dioxide gas (reformed body) in the container 2. Carbon dioxide supply means 3 for supplying C, a heater (heating means) 4 for raising the temperature in the container 2, a pressurizing unit (pressurizing means) 5 for applying pressure to the container 2, and a humidity in the container 2 It comprises a humidity adjusting means 6 for adjusting, and a control panel (control means) 7 for controlling the carbon dioxide supply means 3, the heater 4 and the pressurizing unit 5, respectively.

  The container 2 is a movable box-like object provided with a door (not shown), and a sealing property (airtightness) is ensured by completely closing the door (not shown). The outer periphery of the container 2 is covered with a heat insulating material 8 made of, for example, polyethylene foam, and the container 2 is encased in the heat insulating material 8. A base 9 is provided at the bottom of the container 2, and the concrete product A is placed on the base 9. The container 2 is not limited to a box shape, but may be a bag shape such as polyethylene that can ensure airtightness.

  The container 2 includes a concentration sensor 10 that detects the carbon dioxide C concentration in the container 2, a temperature sensor 11 that detects the temperature in the container 2, a pressure gauge 12 that detects the pressure in the container 2, and a container A humidity sensor 13 for detecting the humidity in 2 is attached. The concentration sensor 10, the temperature sensor 11, the pressure gauge 12, and the humidity sensor 13 are provided with display units 10 a, 11 a, 12 a, and 13 a that display the detection results, respectively, on the outside of the container 2. The gas C concentration, temperature, pressure and humidity can be visually confirmed. The detection data detected by the concentration sensor 10, the temperature sensor 11, and the pressure gauge 12 are transmitted to the control panel 7, respectively.

  The carbon dioxide supply means 3 includes a tank (not shown) in which carbon dioxide C is stored, a delivery unit 14 that sends out the carbon dioxide C, and a gas supply pipe 15 through which the carbon dioxide C delivered from the delivery unit 14 flows. Has been. The first connecting portion 16 attached to the container 2 and communicated with the inside of the container 2 is connected to the delivery portion 14 via a gas supply pipe 15, and the connecting pipe 15 is communicated with the inside of the container 2. . The container 2 is filled with carbon dioxide gas C by the carbon dioxide supply means 3.

The heater 4 is disposed inside the container 2 and is provided on the ceiling in the container 2. The heater 4 is composed of, for example, an electric heater, and is disposed at a substantially central position inside the container 2.
The pressurizing unit 5 is composed of, for example, a compressor, a cylinder, a rubber bag, and the like, and is connected to the second connecting portion 18 attached to the container 2 via the communication pipe 17 and communicated with the inside of the container 2. Yes.

  The humidity adjusting means 6 includes a curing water 19 stretched in the container 2 and a metal salt 20 disposed in the container 2. As the temperature and pressure in the container 2 rise, the curing water 19 is saturated, and the humidity of the container 2 rises. Moreover, the humidity in the container 2 decreases by dissolving the metal salt 20 in the moisture in the container 2. The humidity in the container 2 is adjusted to a range of 30% to 65% by the humidity adjusting means 6.

  The control panel 7 is connected to the concentration sensor 10, the temperature sensor 11 and the pressure gauge 12, respectively. Based on the detection data detected by the concentration sensor 10, the temperature sensor 11 and the pressure gauge 12, the carbon dioxide supply means 3 and the heater 4 and the pressure unit 5 are respectively controlled. The delivery section 14 is controlled by the control panel 7, and the carbon dioxide C concentration in the container 2 is adjusted to a range of 5% to 30%. Further, the heater 4 is controlled by the control panel 7, and the temperature in the container 2 is adjusted to a range of 40 ° C to 65 ° C. Further, the pressurizing unit 5 is controlled by the control panel 7, and the atmospheric pressure in the container 2 is adjusted to a range of atmospheric pressure to 10 atmospheric pressure.

  Next, the usage method of the curing apparatus 1 which consists of an above-described structure is demonstrated.

  First, the process of arrange | positioning the concrete product A in the sealed container 2 is performed. Specifically, a door (not shown) of the container 2 is opened, and the concrete product A is put into the container 2 and placed on the base 9. Then, a door (not shown) of the container 2 is closed to seal the inside of the container 2.

  Next, a step of filling the container 2 with carbon dioxide C by the carbon dioxide supply means 3 is performed. Specifically, the carbon dioxide C is sent from the delivery unit 14 into the gas supply pipe 15, and the carbon dioxide C flowing through the gas supply pipe 15 is passed from the gas supply pipe 15 through the first connection part 16 to the container 2. Let it flow into. At this time, the concentration sensor 10 detects the carbon dioxide C concentration in the container 2 and transmits the detected data to the control panel 7. The control panel 7 controls the sending unit 14 based on the detected data, and stops the sending unit 14 when the carbon dioxide gas C concentration in the container 2 becomes 5 to 30%. Further, the carbon dioxide C concentration in the container 2 can be confirmed on the display unit 10 a of the concentration sensor 10.

  Moreover, the process which adjusts the inside of the container 2 to predetermined temperature with the heater 4 is performed. Specifically, the heater 4 is operated and the temperature in the sealed container 2 is increased by the heat of the heater 4. Since the heat insulating material 8 is covered around the container 2, the temperature rises efficiently. At this time, the temperature sensor 11 detects the temperature in the container 2 and transmits the detected data to the control panel 7. The control panel 7 controls the heater 4 based on the detected data, and stops the heater 4 when the temperature in the container 2 reaches 40 to 65 ° C. Further, the temperature in the container 2 can be confirmed on the display unit 11 a of the temperature sensor 11.

  Moreover, the process which adjusts the inside of the container 2 to predetermined | prescribed atmospheric pressure by the pressurization unit 5 is performed. Specifically, the pressure unit 5 is operated to add a pressure gradient. At this time, the pressure in the container 2 is measured by the pressure gauge 12 and the measured data is transmitted to the control panel 7. The control panel 7 controls the pressurization unit 5 based on the measurement data, and stops the pressurization by the pressurization unit 5 when the atmospheric pressure in the container 2 becomes atmospheric pressure to 10 atm. Further, the atmospheric pressure in the container 2 can be confirmed on the display unit 12 a of the pressure gauge 12.

  At this time, the humidity in the container 2 is managed by the humidity adjusting means 6 so as to be an arbitrary humidity. That is, the curing water 19 stretched in the container 2 is saturated by heat or pressure, and the humidity in the container 2 increases. Moreover, since the metal salt 20 in the container 2 is dissolved in the moisture in the container 2, an increase in the humidity in the container 2 is suppressed, and the humidity in the container 2 is kept at 30 to 65%. Further, the humidity in the container 2 can be confirmed on the display unit 13 a of the humidity sensor 13.

  The curing period of the concrete product A in the container 2 filled with the carbon dioxide gas C is performed within a period in which only the surface portion of the concrete product A is carbonated. In particular, when the concrete product A is a reinforced concrete structure, it is necessary to adjust the curing period so that the reinforcing bars embedded therein are not oxidized and rusted.

  Moreover, you may perform the process of conveying concrete product A to another place, curing in the container 2. FIG. Specifically, the gas supply pipe 15 is removed from the first connection part 16, and the communication pipe 17 is removed from the second connection part 18. At this time, the 1st, 2nd connection parts 16 and 18 are obstruct | occluded and the airtightness in the container 2 is ensured. The carbon dioxide gas C concentration in the container 2 is in the range of 5 to 30%, the temperature in the container 2 is in the range of 40 to 65 ° C., the atmospheric pressure in the container 2 is in the range of atmospheric pressure to 10 atm, and the container The concrete product A is transported together with the container 2 while keeping the humidity in the range of 30 to 65%. Moreover, you may adjust the carbon dioxide gas C density | concentration, temperature, atmospheric pressure, and humidity in conveyance by conveying in the state which connected the carbon dioxide supply means 3 and the pressurization unit 5.

  Next, the case where the concrete specimen is cured using a conventional curing room (neutralization curing tank) that performs carbonation curing is compared with the case where the specimen is cured using the curing apparatus 1 according to the present application. Experiments are performed, and the effects of the curing device 1 having the above-described configuration will be described based on the experimental results.

FIG. 3 (a) is a table showing the materials used for the test body used in this experiment, and FIG. 3 (b) is a composition table for the test body used in this experiment. Is a table showing the fresh properties of the test specimens used in this experiment.
In this experiment, as a test body, two test bodies are prepared with the composition shown in FIG. 3B using the material shown in FIG. The fresh properties of the two specimens are as shown in FIG. 3 (c), and the two specimens are equivalent.

Next, the above-mentioned two test bodies are each cured for one day from placement and solidified. At this time, the curing temperature is 20 ° C. and the curing humidity is 95%.
Next, the two specimens were demolded, one specimen (NO.1) was placed in the neutralization curing tank, and the other specimen (NO.2) was carbon dioxide concentration 100%. It puts in the container 2 of the curing device 1 and cures each of the two specimens for 27 days. At this time, the neutralization curing tank is set to a temperature of 50 ° C., a humidity of 60%, and a carbon dioxide gas concentration of 20%.

  FIG. 4 is a table showing the above experimental results. When the neutralized range (neutralization depth) and the porosity of each specimen were measured after a curing period of 4 weeks, as shown in FIG. 4, the two specimens had equivalent results. . According to the above experimental results, the test body cured in the neutralization curing tank and the test body cured in the curing apparatus 1 according to the present application have the same progress of neutralization, and the curing apparatus 1 It can be seen that sufficient carbonation can be performed.

  According to the curing apparatus 1 having the above-described configuration, the concrete product A is stored in a sealed container 2 filled with carbon dioxide gas C, and the concrete product A is stored in the sealed container 2 with carbon dioxide gas C. Therefore, it is not necessary to seal the space in which the container 2 is placed, the carbon dioxide C can be prevented from flowing out at low cost, and the environmental impact can be reduced. Moreover, since the outflow of the carbon dioxide C can be prevented, the loss amount of the carbon dioxide C filled in the container 2 during curing is reduced, which is economical. In addition, even if other concrete products are carried in and out, the carbon dioxide gas C in the container 2 being cured does not flow out, so that workers in other spaces where there is no carbon dioxide C (small) Carrying in / out work can be performed, and the safety of workers can be ensured.

  Further, since the container 2 is movably arranged, the concrete product A can be transferred while being cured in a carbon dioxide gas C atmosphere, and can be transferred to another stockyard or the like.

  Further, since the carbon dioxide supply means 3 for supplying the carbon dioxide C to the container 2 is provided, the container 2 can be filled with an appropriate amount of carbon dioxide C, and the carbon dioxide C concentration in the container 2 can be filled. Can be maintained at a concentration suitable for curing the concrete product A. Thereby, carbonation curing can be performed effectively and the durability of the concrete product A can be improved.

  Further, since the concentration sensor 10 for detecting the concentration of the carbon dioxide gas C in the container 2 is provided, the concentration control of the carbon dioxide gas C in the container 2 can be performed while maintaining the hermeticity of the container 2. Thereby, a predetermined carbon dioxide gas C concentration can be maintained reliably and easily.

  Moreover, since the humidity adjustment means 6 which adjusts the humidity in the container 2 is provided, the humidity suitable when improving the property of the concrete product A with the carbon dioxide gas C can be maintained. Thereby, carbonation curing can be performed effectively and the durability of the concrete product A can be improved.

  Moreover, since the heater 4 which raises the temperature in the container 2 is provided, the temperature suitable when improving the property of the concrete product A with the carbon dioxide gas C can be maintained. Thereby, carbonation curing can be performed effectively and the durability of the concrete product A can be improved.

  Moreover, since the pressurization unit 5 which applies a pressure in the container 2 is provided, the atmospheric pressure in the container 2 rises and the reaction between the carbon dioxide C and the concrete product A is promoted. Thereby, a curing period can be shortened.

  Further, since the concrete product A is cured in the container 2 filled with carbon dioxide C, the surface portion of the concrete product A is carbonated and densified, and the strength is also increased. As a result, the durability of the concrete product A can be improved, and moisture and gas permeation due to long-term pressure can be prevented.

  Next, a second embodiment of the curing device 2 according to the present invention will be described. Note that the description of the same components as those in the first embodiment is omitted.

[Second Embodiment]
FIG. 2 is a schematic diagram showing a curing device 100 according to the present invention. As shown in FIG. 2, the curing device 100 is provided with exhaust gas supply means 102 that supplies exhaust gas D from a factory or the like into a container 101 in which a concrete product A is stored. The mixed gas B containing the exhaust gas D is filled. The mixed gas B is generated by mixing the carbon dioxide C supplied by the carbon dioxide supply means 103 and the exhaust gas D supplied by the exhaust gas supply means 102.

  The exhaust gas supply means 102 includes a trap 104 that removes dust and the like contained in the exhaust gas D discharged from a factory and the like, and first and second gas supply pipes 105a and 105b. The first gas supply pipe 105a is interposed between an exhaust duct or the like of the factory and the trap 104, and the second gas supply pipe 105b is provided between the trap 104 and the connection portion 106 attached to the container 101. It is intervened. The third gas supply pipe 105c connected to the delivery unit 107 constituting the carbon dioxide supply means 103 is connected to the second gas supply pipe 105b. Further, an exhaust gas pipe 108 is connected to the container 101, and the mixed gas B in the container 101 is appropriately discharged.

  The curing apparatus 100 having the above-described configuration is provided with the exhaust gas supply means 102 that supplies the exhaust gas D. Since the mixed gas B in the container 101 contains the exhaust gas D, the environment is affected. The exhaust gas D can be reused efficiently and energy can be saved. As a result, environmental destruction can be suppressed and costs can be reduced.

  The first and second embodiments of the cured body curing device according to the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and may be appropriately selected without departing from the scope of the present invention. It can be changed. For example, in the above-described embodiment, the curing devices 1 and 100 for curing the concrete product A are described, but the cured body according to the present invention is made of a mortar product or other cement-based curable substance. It may be a thing or a resin-made cured body.

  In the embodiment described above, carbon dioxide gas C is used as the reforming treatment body. However, the reforming treatment body according to the present invention may be carbonated water or the container may be filled with carbonated water. Further, the modified body can be appropriately changed according to the cured body to be cured, and a gas other than carbon dioxide C or a liquid other than carbonated water may be used.

It is a schematic diagram for demonstrating 1st Embodiment of the curing device of the hardening body which concerns on this invention. It is a schematic diagram for demonstrating 2nd Embodiment of the curing device of the hardening body which concerns on this invention. (A) shows the use material of the test body used for the experiment which compares the case where a concrete test body is cured using a neutralization curing tank, and the case where a test body is cured using the curing apparatus which concerns on this application. It is a table | surface, (b) is a compounding table | surface of the test body used for experiment, (c) is a table | surface which shows the fresh property of the test body used for experiment. It is a table | surface which shows the experimental result of the experiment which compares the case where a concrete test body is cured using a neutralization curing tank, and the case where a test body is cured using the curing apparatus which concerns on this application.

Explanation of symbols

1,100 Curing device 2,101 Container 3,103 Carbon dioxide supply means (supply means)
4 Heater (heating means)
5 Pressurizing unit (pressurizing means)
6 Humidity adjustment means 10 Concentration sensor (concentration detection means)
102 Exhaust gas supply means A Concrete product (hardened body)
B Mixed gas (reformed body)
C Carbon dioxide gas (modified body)
D exhaust gas

Claims (9)

  A curing apparatus for curing a cured body, comprising: a container in which the cured body is stored and hermetically sealed; and the container is filled with a modified body that improves the properties of the cured body. In the curing body curing device according to claim 1,
Curing device curing device, wherein the container is movably disposed. In the curing body curing device according to claim 1 or 2,
A curing body curing apparatus, comprising a supply means for supplying the modified body into the container. In the curing body curing device according to any one of claims 1 to 3,
A curing body curing device, wherein the container is provided with a concentration detection means for detecting the concentration of the modified body in the container. In the curing body curing device according to any one of claims 1 to 4,
A curing apparatus for curing a cured body, comprising humidity adjusting means for adjusting humidity in the container. In the curing body curing device according to any one of claims 1 to 5,
A curing apparatus for curing a cured body, comprising heating means for increasing the temperature in the container. In the curing body curing device according to any one of claims 1 to 6,
A curing unit curing apparatus, comprising a pressurizing means for applying pressure to the container. In the curing device of the hardening body in any one of Claim 1 to 7,
The curing body curing apparatus, wherein the modified body is made of carbon dioxide or carbonated water, and the hardened body is made of a cement-based curable substance. In the hardening body curing device according to claim 8,
An apparatus for curing a cured body, comprising exhaust gas supply means for supplying exhaust gas, wherein the reforming body in the container contains exhaust gas.

Images