JP2014084613A - Method for curing tunnel lining concrete - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for curing tunnel lining concrete which can suppress occurrence of initial cracking by controlling in such a manner that the surface temperature and the surface moisture thereof become prescribed temperature and moisture during an initial curing period after form removal.SOLUTION: Internal thermometers 30 are embedded and installed in concrete and surface thermometers 31, surface moisture meters 32 are disposed on an inside surface of the concrete, and a wet layer 27 to which wetting water is supplied, an electric heating material 28 for warming and a heat insulation layer 26 are mounted to cover the inside surface of the concrete. Supply of the wetting water to the wet layer 27 is controlled by a control device 33 so that a moisture measured by the surface moisture meters 32 becomes 80% or more, and warming of the wet layer 27 by the electric heating material 28 for warming is controlled by the control device 33 so that a surface temperature of a lining concrete 10 measured by the surface thermometers 31 becomes equal to or more than the internal temperature of the lining concrete varying along with progression of a hydration reaction measured by the internal thermometers 30.

Description

  The present invention relates to a curing method for tunnel lining concrete and a curing method for mass-working concrete, and more particularly to a tunnel lining employed in a heating and humid curing process performed after the concrete is placed and subsequently to the curing process in the mold. The present invention relates to a curing method for concrete and a curing method for mass concrete.

  For example, in tunnel construction such as a mountain tunnel, after tunnel excavation, concrete is sprayed onto the inner wall surface of the tunnel to perform primary lining, and then a tunnel lining formwork is installed. Generally, lining concrete having a predetermined thickness is formed by placing concrete in a space between the tunnel and the inner wall surface of the tunnel.

  Also, if the lining concrete that covers the inner wall surface of the tunnel is left as it is after demolding, cracking due to drying shrinkage will occur and the quality will deteriorate, so the surface of the lining concrete formed should be kept in a wet state. Various techniques have been developed to prevent cracking by preventing the lining concrete from drying by curing (for example, Patent Document 1). In the technique of Patent Document 1, a tunnel lining formwork is installed using a known mobile centle that can move in the extension direction of the tunnel mine, and concrete is cast, thereby covering a predetermined thickness. In addition to forming the reinforced concrete, the surface of the lining concrete after demolding is kept moist and cured by installing a curing device that can be moved in the tunnel mine after the mobile centre. It has become.

JP 2010-19067 A JP 11-322470 A

  On the other hand, it is known that the lining concrete covering the inner wall of the tunnel is susceptible to the occurrence of cracks due to the shrinkage of the surface and the quality such as long-term durability depending on the curing environment after placing the concrete. It has been. In particular, lining concrete formed for the reason that the hydration reaction of concrete is not sufficiently promoted depending on the curing environment in the initial curing period of about 7 days after casting, for example, after casting. Even if the surface is kept in a wet state and cured, initial cracking may not be sufficiently suppressed.

  In addition, for example, in Patent Document 2, when concrete is cast in the cold to form mass concrete, the temperature of the concrete itself is measured by a temperature sensor disposed inside the concrete, and is disposed inside and outside the curing enclosure. Measure the ambient temperature with a temperature sensor, for example, keep the internal temperature of concrete at 2 ℃ or higher and keep the difference between the ambient temperature and the internal temperature of concrete within 25 ℃ in the curing enclosure. Although a concrete curing system for controlling on / off of the installed jet heater is disclosed, even if the temperature control described in Patent Document 2 is applied to the tunnel lining concrete covering the inner wall surface of the tunnel, the surface of the tunnel lining concrete is It is difficult to sufficiently suppress the occurrence of initial cracks.

  In the present invention, during the initial curing period of, for example, about 7 days after demolding, the surface temperature and the humidity of the lining concrete are easily controlled so as to become a predetermined temperature and humidity, and initial cracks are generated. It aims at providing the curing method of the tunnel lining concrete which can suppress effectively generating.

  In addition, the present invention easily controls the surface temperature and the humidity of the lining concrete so as to become a predetermined temperature and humidity during the initial curing period of, for example, about 7 days after demolding. It aims at providing the curing method of the mass concrete which can suppress effectively that a crack generate | occur | produces.

  The present invention provides a tunnel lining formwork and casts concrete to cover the inner wall surface of the tunnel to form tunnel lining concrete. This is a curing method for tunnel lining concrete that is used in the heating and moistening curing process that is performed following the curing process in the mold until it is done. An internal thermometer is embedded in the placed concrete. In addition, a surface thermometer and a surface hygrometer are disposed on the surface of the placed concrete, and the surface of the concrete on which the surface thermometer and the surface hygrometer are disposed is covered with curing water. A heating layer is provided, and a heating electric material is disposed in the wetting layer, and a heat insulating layer is attached to cover the surface of the wetting layer on which the heating electric material is disposed, Surface moisture The control device controls the supply of curing water to the wet layer so that the humidity measured by the meter is 80% or more, and the surface temperature of the lining concrete measured by the surface thermometer is the internal temperature. The control device adds the wet layer by the heating electric heating material so that the temperature is equal to or close to the internal temperature of the lining concrete that changes with the progress of the hydration reaction. The object is achieved by providing a method for curing tunnel lining concrete that controls the temperature.

  And the curing method of the tunnel lining concrete of the present invention, the temperature difference between the internal temperature of the lining concrete measured by the internal thermometer and the surface temperature of the lining concrete measured by the surface thermometer, It is preferable that the heating of the wet layer by the heating electric heating material is controlled by the controller so that the temperature is within 3 ° C.

  In the curing method for tunnel lining concrete according to the present invention, it is preferable that the internal thermometer and the surface thermometer are thermocouples, and the surface hygrometer is an electronic hygrometer.

  Furthermore, the curing method for tunnel lining concrete of the present invention is preferably controlled so that the temperature of the curing water supplied to the wet layer is equal to or close to the internal temperature of the lining concrete. .

  Further, the present invention provides a curing process in the mold until the mold is removed after the concrete is cast in the construction for forming the mass concrete by installing the mold and placing the concrete. Is a curing method for mass concrete that is employed in the heating and humid curing process that is performed subsequently to an embedded thermometer in the placed concrete, and on the surface of the placed concrete, A surface thermometer and a surface hygrometer are provided, and a wet layer to which curing water is supplied is provided to cover the surface of the concrete on which the surface thermometer and the surface hygrometer are provided. A heating electric material is arranged on the layer, and a heat insulating layer is attached to cover the surface of the wet layer on which the heating electric material is arranged, and the humidity measured by the surface hygrometer is 80% or more It will be In addition, the control device controls the supply of curing water to the wet layer, and the surface temperature of the mass concrete measured by the surface thermometer is measured by the internal thermometer. By providing a mass concrete curing method for controlling the heating of the wet layer by the heating electric material by a control device so that the temperature is equal to or close to the internal temperature of the changing mass concrete, The above objective has been achieved.

  According to the curing method for tunnel lining concrete or the curing method for mass concrete according to the present invention, the temperature and surface humidity of the lining concrete and the mass concrete during the initial curing period of, for example, about 7 days after demolding. Can be easily controlled so as to have a predetermined temperature and humidity, and the occurrence of initial cracks can be effectively suppressed.

1 is a schematic cross-sectional view illustrating a tunnel lining concrete cured by a method for curing tunnel lining concrete according to a preferred embodiment of the present invention, and a mobile centle for installing a tunnel lining formwork. 1 is a schematic cross-sectional view illustrating a curing device used in a method for curing tunnel lining concrete according to a preferred embodiment of the present invention. It is an expanded sectional view explaining the structure of the curing mat attached to the curing apparatus shown in FIG. It is explanatory drawing of the system configuration | structure for enforcing the curing method of the tunnel lining concrete which concerns on preferable one Embodiment of this invention. It is a chart which illustrates the data processing flow in a heating wet curing process. (A) is a graph explaining the tensile stress reduction effect, (b) is a table explaining the improvement effect of the crack index at the time of young age.

  A tunnel lining concrete curing method according to a preferred embodiment of the present invention is a tunnel cover installed using a known mobile centle 11 as shown in FIG. 1 in tunnel construction for constructing a mountain tunnel, for example. The lining concrete 10 formed by placing concrete in the space between the work form frame 12 and the inner wall surface 20a of the tunnel 20 covered with primary lining preferably by shotcrete is cast into the concrete. After setting, after removing from the mold, for example, during the initial curing period of about 7 days, it is effective that the initial cracking (cracking at the young age) occurs especially on the surface by curing in an appropriate curing environment. Therefore, the lining concrete 10 having excellent quality can be obtained.

  That is, since the lining concrete 10 covering the inner wall surface 20a of the tunnel 20 is constructed in the tunnel pit 20b which is a closed space, the quality is considered to be easily influenced by the curing environment. On the other hand, the lining concrete 10 after placing the concrete is hydrated by keeping the temperature difference between the inside of the lining concrete 10 and the inner surface of the tunnel mine 20b side as small as possible during curing. It is considered that the durability of the lining concrete 10 can be effectively improved by promoting the reaction. In particular, in the period of initial curing after demolding of the tunnel lining form 12, the temperature difference between the inside of the lining concrete 10 and the inner surface is kept as small as possible, which is different from cracks due to drying shrinkage. As a factor, for example, it is considered that generation of cracks due to shrinkage strain caused by a temperature difference between the inside and the inner surface of concrete can be effectively suppressed. The inventor of the present application has developed the following tunnel lining concrete curing method based on such rational reasoning.

  And the curing method of the tunnel lining concrete of this embodiment is the construction which forms the tunnel lining concrete by covering the inner wall surface of the tunnel 20 by installing the tunnel lining formwork 12 and placing the concrete. A curing method employed in a heating and humid curing process, which is performed subsequent to the curing process in the mold until the mold 12 is demolded after placing the concrete, and is shown in FIGS. As shown in FIG. 4, an internal thermometer 30 is embedded in the placed concrete (see FIG. 4), and the surface thermometer 31 is placed on the inner surface, which is the surface of the placed concrete on the tunnel mine 20b side. And a surface hygrometer 32 (see FIG. 4), and the wet layer 27 to which the curing water is supplied covering the inner surface of the concrete on which the surface thermometer 31 and the surface hygrometer 32 are disposed. In addition, the heating electric material 28 is disposed inside the wet layer, and the heat insulating layer 26 is attached so as to cover the inner surface of the wet layer 27 on which the heating electric material 28 is disposed (see FIG. 3). ), The supply of curing water to the wet layer 27 is controlled by the control device 33 (see FIG. 4) so that the humidity measured by the surface hygrometer 32 is 80% or more, and is measured by the surface thermometer 31. The control device so that the surface temperature of the lining concrete 10 is equal to or close to the internal temperature of the lining concrete 10 which is measured by the internal thermometer 30 and changes as the hydration reaction proceeds. By 33, the heating of the wet layer 27 by the heating electric heating material 28 is controlled.

  In the method for curing tunnel lining concrete according to this embodiment, the temperature of the curing water supplied to the wet layer 27 is preferably equal to or approximate to the internal temperature of the lining concrete 10 measured by the internal thermometer 30. The temperature is controlled by the control device 33 so as to reach the temperature.

  In this embodiment, as shown in FIG. 1, the tunnel lining formwork 12 for forming the lining concrete 10 to be cured is preferably a movable centle 11, and the inner wall surface 20a of the tunnel 20 is set inside. It is installed to cover from. The mobile centle 11 is a well-known formwork device for tunnel construction having the same configuration as the mobile centre described in, for example, Japanese Patent Application Laid-Open No. 2009-186184. The mobile centle 11 mainly includes a tunnel lining form 12 disposed with a space corresponding to the thickness of the lining concrete 10 between the inner wall surface 20a of the tunnel 20 and the tunnel covering. A support frame 13 that supports the work form frame 12 and a traveling rail 14 that is laid in the extending direction of the tunnel 20 in the bottom plate portion 20c of the tunnel 20 and supports the support frame 13 so as to travel.

  The tunnel lining formwork 12 is attached to the support frame 13 in a state in which the tunnel lining formwork 12 can be advanced and retracted in the radial direction via a plurality of extension jacks 15. The tunnel lining formwork 12 is arranged along the inner wall surface 20a of the tunnel 20 and casts concrete from a state in which the space for placing the lining concrete 10 is held between the inner wall surface 20a. After initial strength is expressed in the in-frame curing process, the mold is removed from the formed lining concrete 10 by being pulled away radially inward. The tunnel lining formwork 12 after being removed is moved forward along the traveling rail 14 along the traveling rail 14 in the extending direction of the tunnel 20 to place the lining concrete 10 in the next construction span. Is to be done.

  In the present embodiment, the mobile centile 11 has a length in the extending direction of the tunnel 20 of, for example, about 10.5 m, and thereby, for example, a length of about 10.5 m is set as one construction span. The concrete 10 can be formed while being sequentially placed in the extending direction of the tunnel 20.

  The heating and humid curing process, which is performed subsequent to the curing process in the mold after the concrete is placed and before the tunnel lining mold 12 is removed, is, for example, an initial curing process of about 7 days. It is performed using the curing device 16 as shown in FIG. The curing device 16 can be used by appropriately improving the known curing device described in JP 2010-19067 A, for example. A plurality of curing devices 16 are arranged on the traveling rail 14 following the mobile centile 11. In this embodiment, the curing device 16 is mainly movable in the vertical direction and the inner periphery of the tunnel 20. A plurality of shell structures 19 having an arch shape along the surface 20a and having a curing mat 18 on the outer periphery, and a movable frame 17 and a shell structure 19 are provided. The support member 23 is formed of a turnbuckle-type rod member that can be expanded and contracted and a wire member that can be adjusted in length.

  In the present embodiment, the shell structure 19 is, for example, a substantially straight shape in an unloaded state, and is curved so as to follow the inner peripheral surface 20a of the tunnel 20 using the support member 23 provided on the movable mount 17 at the time of installation. A plurality of frame members 24 that extend in the circumferential direction of the tunnel 20 and can be deformed (elastically deformed) and are arranged substantially in parallel with an interval in the extending direction of the tunnel 20, and the extending direction of the tunnel 20 A connecting member (not shown) that extends to the frame member 24 and connects the frame member 24 to each other, and a curing mat 18 and an outer panel 25 that are supported by the frame member 24 and the connecting member and disposed on the outer peripheral portion thereof. (Refer to FIG. 3).

  The frame member 24 is, for example, a pipe-shaped member made of glass fiber reinforced plastic having high strength, high toughness, and high elasticity, and is easily curved and deformed from a substantially linear shape, and is made of a rod member or a wire member. By adjusting the length of the support member 23, the curing mat 18 disposed at the outer peripheral portion is deformed along the inner peripheral surface of the lining concrete 10 after the tunnel lining formwork 12 is removed. The lining concrete 10 can be brought into close contact with the inner peripheral surface of the lining concrete 10.

  Moreover, the shell structure 19 shortens the supporting member 23 made of, for example, a rod member from the state in which the curing mat 18 is in close contact with the inner peripheral surface of the lining concrete 10, and lowers the movable mount 17, thereby curing the curing structure 17. The mat 18 is moved away from the inner peripheral surface of the lining concrete 10 so that the curing device 16 can be sequentially moved forward along the traveling rail 14 in the extending direction of the tunnel 20 along the movable center 11. It has become. As a result, the lining concrete 10 formed using the mobile centle 11 in the front construction span is moved to the front construction span, and then the curing device 16 is moved. Thus, the heating and humid curing process can be sequentially performed.

  In the present embodiment, the curing mat 18 supported by the frame member 24 and the connecting member and disposed on the outer peripheral portion thereof is, for example, a heat insulating layer 26 attached to the outer peripheral surface of the outer panel 25 as shown in FIG. And a wetting layer 27 laminated on the outer peripheral surface of the heat insulating layer 26. Between the heat insulating layer 26 and the wet layer 27, an electric heating material 28 for heating is interposed between them. Has been placed. Accordingly, a wet layer 27 to which curing water is supplied is provided so as to cover the inner surface of the placed concrete, and a heating electric heating material 28 is disposed inside the wet layer 27, and further for heating. The heat insulating layer 26 is attached so as to cover the inner surface of the wet layer 27 on which the electric heating material 28 is disposed.

  In the present embodiment, the heat insulating layer 26 is provided with a thickness of, for example, about 10 mm using a foaming member such as a sponge having a gap such as closed cells or open cells therein, and has elasticity. Yes.

  The wetting layer 27 can be formed with a thickness of, for example, about 10 mm using various known moisturizing mats that can absorb moisture and have physical properties that can retain the absorbed moisture. As the moisturizing mat used as the wet layer 27, for example, a commercial name “Uruon mat” (manufactured by Fujimori Sangyo Co., Ltd.), which is a commercially available concrete heat retaining / humidifying mat, can be used. The wet layer 27 is connected to a well-known automatic water supply facility (not shown) having a boiler function capable of heating. Desired water that has been appropriately heated is controlled by the control device 33 from the automatic water supply facility. The amount of water can be supplied to the wet layer 27.

  The heating electric heating material 28 is made of, for example, a known sheet heating element formed in a sheet shape, and generates heat when energized to heat the lining concrete 10 during curing. The heating electric heating material 28 has a thickness of, for example, about 2 mm and is formed in a band shape of, for example, a width of about 300 mm, and is continuously laid in the circumferential direction of the tunnel 20 and extends the tunnel 20. In the direction, for example, it is installed so as to be sandwiched between the heat insulating layer 26 and the wet layer 27 in a state of being laid in parallel at a center-to-center pitch of about 1 m with an interval of about 700 mm. The heating electric heating material 28 has an automatic heating function, and can heat the wet layer 27 so as to have a desired temperature controlled by the control device 33.

  In the present embodiment, the curing mat 18 is attached to the outer peripheral portions of the frame member 24 and the connecting member with the outer panel 25 interposed therebetween. By interposing the outer surface panel 25, the pressing force from the frame member 24 and the connecting member by the curing device 16 is received by the outer surface panel 25 and then transmitted to the curing mat 18. It becomes possible to make it adhere to the inner surface of the lining concrete 10 in a stable state. As the outer panel 25, for example, a keystone plate or a corrugated plate having a large number of concave portions and convex portions arranged side by side is used as a plate material that can be bent along the shape of the outer peripheral surface of the frame member 24. Can do.

  In the present embodiment, an internal thermometer 30 for measuring the internal temperature of the lining concrete 10 being hardened by a hydration reaction between water and cement is embedded in the placed concrete. deep. A surface thermometer 31 for measuring the surface temperature of the lining concrete 10 is installed on the inner surface of the placed concrete, and a surface hygrometer 32 for measuring the humidity of the surface of the lining concrete 10 is provided. Install it. Here, the internal thermometer 30 is fixed at a desired position in the concrete placement space when placing concrete using the tunnel lining formwork 12 installed in each construction span. Thus, it can be easily embedded and installed inside the lining concrete 10. The surface thermometer 31 and the surface hygrometer 32 are placed at desired positions on the outer surface of the tunnel lining formwork 12 when placing concrete using the installed tunnel lining formwork 12 in each construction span. It can be easily installed on the inner surface of the lining concrete 10.

  For the internal thermometer 30 and the surface thermometer 31, various known thermocouples can be preferably used. In the present embodiment, as shown in FIG. At three locations in the circumferential direction of the end portions and the side wall portions on both sides, the internal thermometer 30 is disposed at the center of the thickness of the lining concrete 10 and the surface thermometer 31 is disposed on the inner surface of the lining concrete 10. And it is provided in a paired state.

  As the surface hygrometer 32, various known electronic hygrometers can be preferably used. In the present embodiment, as shown in FIG. 4, for example, the inner side of the top end portion of the lining concrete 10 in each construction span. For example, the surface of the tunnel 20 is provided in two locations at an interval of about 6 m in the axial direction of the tunnel 20.

  The internal thermometer 30, the surface thermometer 31, and the surface hygrometer 32 are connected to a personal computer 33a constituting the control device 33, and according to a predetermined control program, for example, the inside of the lining concrete 10 every hour. The temperature, surface temperature, and surface humidity are automatically measured, and the measured temperature and humidity measurement data can be taken into the personal computer 33a. The personal computer 33a stores the captured measurement data in the storage unit according to a predetermined control program, performs various data processing based on the captured measurement data, and configures the control device 33 together with the personal computer 33a. Through the board 33b, the temperature and humidity of the inner surface of the lining concrete 10 in the heating and humid curing process are managed in accordance with a data processing flow as shown in FIG. 5, for example.

  That is, in the humidity control of the inner surface of the lining concrete 10, the wet layer 27 of the curing mat 18 is preferably used from an automatic water supply facility (not shown) so that the surface humidity of the lining concrete 10 is always kept at 85% or more. It is designed to control the supply of curing water. For example, when the surface humidity of the lining concrete 10 measured by the surface hygrometer 32 is less than or less than 85%, the curing water is supplied from the automatic water supply equipment, and the surface humidity measured by the surface hygrometer 32 is used. Water is automatically supplied until the water reaches 90% or more, and the wet curing is continued.

  Here, the humidity of the inner surface of the lining concrete 10 in the heating and humid curing process needs to hold 80% or more, preferably 85% or more, particularly preferably 85 to 90%. preferable. By maintaining the humidity of the inner surface of the lining concrete 10 at 80% or more in the heating and humid curing process, it is possible to effectively avoid the occurrence of cracks due to drying shrinkage.

  In this embodiment, the temperature of the curing water (wet water) supplied to the wet layer is equal to or approximate to the internal temperature of the lining concrete 10 measured by the internal thermometer 30. It is preferable to control a known automatic water supply facility having a boiler function that can be heated by the control panel 33b of the control device 36. Since the temperature of the wet water supplied to the wet layer is equal to or close to the internal temperature of the lining concrete 10, While preventing the temperature difference from increasing, the hydration reaction is promoted, and the occurrence of cracks due to shrinkage strain caused by the temperature difference between the interior and the inner surface of the concrete is further effectively suppressed. It becomes possible.

  In the temperature control of the inner surface of the lining concrete 10, the internal temperature is adjusted so that the surface temperature of the lining concrete 10 is synchronized with a gradual change in the internal temperature of the lining concrete 10 as the hardening proceeds due to a hydration reaction. The temperature difference (internal temperature-surface temperature) between the internal temperature of the lining concrete 10 measured by the meter 30 and the surface temperature of the lining concrete 10 measured by the surface thermometer 31 is, for example, within 3 ° C. As described above, the controller 33 controls the heating of the wet layer 27 by the heating electric heating material 28. For example, when the temperature difference between the internal temperature measured by the internal thermometer 30 and the surface temperature measured by the surface thermometer 31 exceeds or is about to exceed 3 ° C., for example, the heating material 28 for heating is used. Thus, the wet layer 27 is automatically heated until the temperature difference between the internal temperature of the lining concrete 10 and the surface temperature is within 3 ° C., for example, and the wet curing is continued.

  Here, in this embodiment, the temperature difference between the internal temperature of the lining concrete 10 measured by the internal thermometer 30 and the surface temperature of the lining concrete 10 measured by the surface thermometer 31 (internal temperature−surface temperature). ) Is preferably controlled so as to be within 3 ° C., and the heating of the wetting layer 27 with the heating electric material 28 is preferably controlled within 2 ° C. It is particularly preferable to control the heating. By controlling the heating of the wet layer 27 so that the temperature difference between the internal temperature of the lining concrete 10 and the surface temperature is within 3 ° C., the hydration reaction is promoted and the internal and internal surfaces of the concrete are accelerated. It is possible to more effectively suppress the generation of cracks due to shrinkage strain that occurs with a temperature difference.

  Moreover, in this embodiment, according to the data processing flow which gives priority to the humidity management of the inner surface of the lining concrete 10 over the temperature management of the inner surface of the lining concrete 10, in the heating and humid curing process, The temperature and humidity of the inner surface can also be managed. For example, in order to keep the humidity of the inner surface of the lining concrete 10 at 85% or more, when the curing water having a low temperature which is not heated is supplied from the automatic water supply equipment to the wet layer 27, the water is supplied. The temperature of the inner surface of the lining concrete 10 is lowered by the cured water. In such a case, priority is given to maintaining the humidity of the inner surface of the lining concrete 10 at 85% or more. The temperature of the inner surface of the lining concrete 10 can be controlled to return to a predetermined temperature later.

  Furthermore, in this embodiment, the measurement data of the humidity and temperature of the inner surface of the lining concrete 10 are automatically transmitted to the field office every hour, for example, by wire or wirelessly from the tunnel mine 20b. If the measured value deviates from the humidity or temperature control value, for example, an email is automatically distributed to the employee's mobile phone, and an immediate correction system is put in place. A reliable curing effect of the wrought concrete 10 can be obtained.

  And according to the curing method of the tunnel lining concrete of this embodiment provided with the above-mentioned structure, the surface temperature and surface humidity of the lining concrete 10 during the initial curing period of, for example, about 7 days after demolding. Can be easily controlled so as to have a predetermined temperature and humidity, and the occurrence of initial cracks can be effectively suppressed.

  That is, according to the curing method for tunnel lining concrete of the present embodiment, the internal thermometer 30 is embedded in the placed concrete, and the surface thermometer 31 and the surface are placed on the surface of the placed concrete. A hygrometer 32 is provided, and a wet layer 27 to which curing water is supplied is provided to cover the surface of the concrete on which the surface thermometer 31 and the surface hygrometer 32 are provided. A heating electric material 28 is disposed, and a heat insulating layer 26 is attached so as to cover the surface of the wet layer 27 on which the heating electric material 28 is disposed, and is measured by the surface hygrometer 32 in the heating and humid curing process. The surface temperature of the lining concrete 10 measured by the surface thermometer 31 is controlled by the control device 33 so that the humidity is 80% or more. The control device 33 controls the heating of the wet layer 27 by the heating electric heating material 28 so that the temperature becomes equal to or close to the internal temperature of the lining concrete 10 measured by the meter 30. Yes.

  Therefore, according to the present embodiment, in the heating and humid curing process, which is a period of initial curing after removing the tunnel lining formwork 12, the inner thermometer 30 and the surface thermometer 31 are applied to the lining concrete 10. The control device 33 has a simple configuration in which the surface hygrometer 32 is disposed, the inner surface of the lining concrete 10 is covered, and the wet layer 27, the heating electric heating material 28, and the heat insulating layer 26 are attached. Through this, it becomes possible to easily maintain the humidity of the inner surface of the lining concrete 10 to be preferably 85% or more, and the temperature of the inner surface of the lining concrete 10 is equal to the internal temperature. It is possible to easily control the temperature so as to reach a temperature close to or close to the temperature, so that the temperature difference between the inside and the inner surface of the lining concrete 10 is kept as small as possible so that hydration can be achieved. As a factor different from cracks due to drying shrinkage, the initial cracking is effectively reduced by reducing the tensile stress due to shrinkage strain caused by the temperature difference between the inside and the inner surface of the concrete. Can be suppressed.

  Moreover, simply heating the inner surface of the lining concrete 10 cannot cope with the change in the internal temperature of the lining concrete 10 due to the hydration reaction, and the temperature difference between the internal temperature and the surface temperature increases. On the contrary, temperature stress is generated, but in the present embodiment, by the above-described automatic temperature control function, the temperature difference between the internal temperature of the lining concrete 10 and the surface temperature is kept to a minimum, and thus, due to the temperature stress. The occurrence of cracks can be effectively suppressed.

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, the internal thermometer and the surface thermometer do not necessarily need to be a thermocouple, and various other known thermometers that can measure the temperature of the inside or the surface of concrete can be used. The surface hygrometer is not necessarily an electronic hygrometer, and various other known hygrometers capable of measuring the humidity of the concrete surface can be used.

  In addition, the curing method of the present invention includes installing a formwork in addition to the construction of covering the inner wall surface of the tunnel to form the tunnel lining concrete by installing the tunnel lining formwork and placing concrete. By placing concrete, it can also be employed in construction for forming mass concrete.

  In other words, in the construction of forming mass concrete by installing a formwork and placing concrete, after the concrete is placed, it is performed following the curing process in the formwork until the mold is removed. In the heating and humid curing process, an internal thermometer is embedded in the placed concrete, a surface thermometer and a surface hygrometer are disposed on the surface of the placed concrete, and Covering the surface of the concrete on which the surface thermometer and the surface hygrometer are arranged, a wet layer to which curing water is supplied is provided, a heating electric material is disposed in the wet layer, and the heating electric heat is further provided. Cover the surface of the wet layer where the material is placed, attach a heat insulation layer, and control the supply of curing water to the wet layer by the controller so that the humidity measured by the surface hygrometer is 80% or more And surface thermometer Thus, by the control device, the surface temperature of the mass concrete measured is equal to or close to the internal temperature of the mass concrete measured by the internal thermometer, which changes with the progress of the hydration reaction, Heating and humid curing can be performed by controlling the heating of the wet layer by the electric heating material for heating.

  Thus, as in the case of the tunnel lining concrete described above, the surface temperature and surface humidity of the mass concrete become a predetermined temperature and humidity during the initial curing period of, for example, about 7 days after demolding. Thus, it is possible to effectively control the occurrence of initial cracks.

The inventors of the present invention maintain the humidity of the surface of the lining concrete at 85% or more by using the curing method of the tunnel lining concrete of the present invention at the actual tunnel construction site, and the internal temperature of the lining concrete. The temperature difference between the surface temperature and the surface temperature is controlled to be within 3 ° C., and the warming and humid curing process is performed. As shown in FIGS. 6A and 6B, the warming and humid curing is not performed. Compared with the case where standard curing (standard plan) is performed, after demolding, for example, the tensile stress (N / mm ² ) of the inner surface of the lining concrete of age 4 days is 1.18 (standard curing). N / mm ² ) was confirmed to be reduced to 0.93 (N / mm ² ). Moreover, after demolding, it was confirmed that the crack index (tensile strength / tensile stress) of lining concrete, for example, 4 days of age, was improved by 34% from 1.16 to 1.55 of the standard curing. .

DESCRIPTION OF SYMBOLS 10 Covering concrete 11 Mobile centr 12 Tunnel lining formwork 16 Curing apparatus 17 Moving stand 18 Curing mat 19 Shell structure 20 Tunnel 23 Support member 24 Frame member 25 Outer panel 26 Heat insulation layer 27 Moisturizing mat 28 Heating material for heating 30 Internal thermometer 31 Surface thermometer 32 Surface hygrometer 33a Personal computer 33b Control panel

Claims (5)

By constructing tunnel lining formwork and placing concrete, in the construction to cover the inner wall surface of the tunnel to form tunnel lining concrete, after the concrete is placed, until the mold is removed A curing method for tunnel lining concrete employed in a heating and humid curing process performed subsequent to the curing process in the mold of
An internal thermometer is buried in the placed concrete, and a surface thermometer and a surface hygrometer are arranged on the surface of the placed concrete.
And covering the surface of the concrete on which the surface thermometer and the surface hygrometer are disposed, providing a wet layer to which curing water is supplied, and arranging a heating electric heating material in the wet layer, Covering the surface of the wet layer where the heating material for heating is disposed, and attaching a heat insulating layer,
The control device controls the supply of curing water to the wet layer so that the humidity measured by the surface hygrometer is 80% or more, and the surface temperature of the lining concrete measured by the surface thermometer is The wetting by the heating electric material by the control device so that the temperature is equal to or close to the internal temperature of the lining concrete, which is measured by the internal thermometer and changes as the hydration reaction proceeds. A method of curing tunnel lining concrete that controls the heating of the layer.   By the control device, the temperature difference between the internal temperature of the lining concrete measured by the internal thermometer and the surface temperature of the lining concrete measured by the surface thermometer is within 3 ° C. The method for curing tunnel lining concrete according to claim 1, wherein heating of the wet layer by a heating electric heating material is controlled.   The tunnel lining concrete curing method according to claim 1 or 2, wherein the internal thermometer and the surface thermometer are thermocouples, and the surface hygrometer is an electronic hygrometer.   The tunnel lining concrete according to any one of claims 1 to 3, wherein the temperature of the curing water supplied to the wet layer is controlled to be equal to or close to the internal temperature of the lining concrete. Curing method. By installing concrete and placing concrete, in the construction to form mass concrete, it is performed following the curing process in the mold until the mold is removed after casting the concrete. A mass concrete curing method employed in a warm and humid curing process,
An internal thermometer is buried in the placed concrete, and a surface thermometer and a surface hygrometer are arranged on the surface of the placed concrete.
And covering the surface of the concrete on which the surface thermometer and the surface hygrometer are disposed, providing a wet layer to which curing water is supplied, and arranging a heating electric heating material in the wet layer, Covering the surface of the wet layer where the heating material for heating is disposed, and attaching a heat insulating layer,
The control device controls the supply of curing water to the wet layer so that the humidity measured by the surface hygrometer is 80% or more, and the surface temperature of the mass concrete measured by the surface thermometer is The control device controls the wet layer by the heating electric material so that the temperature is equal to or close to the internal temperature of the mass concrete that changes as the hydration reaction progresses, as measured by an internal thermometer. Mass concrete curing method to control heating.

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