JP2019073962A - Method and device for predicting leveling work enabling period of concrete and method for constructing concrete - Google Patents

Abstract

To provide a method and device for predicting a leveling work enabling period of concrete capable of easily grasping a leveling work enabling period before starting a leveling work of a concrete surface and a method for constructing concrete.SOLUTION: The method includes: a step S1 for considering that an air temperature of a construction time zone and a temperature of concrete are in a correlation relationship, and for applying a predicted air temperature predicted in the construction time zone to a relation between inclination information of an approximate expression expressing a relation between a preliminarily grasped penetration resistance value and a lapse time and the temperature of concrete to calculate inclination information; steps S2, S3 for estimating a conductivity reduction time corresponding to the calculated inclination information from a relation between a time from a preliminarily grasped water injection time to the conductivity reduction time and the inclination information; a step S4 for estimating a relation between the penetration resistance value and the lapse time corresponding to the calculated inclination information; and steps S5, S6 for predicting a leveling time enabling period from the estimated relation between the penetration resistance value and the lapse time and the conductivity reduction time.SELECTED DRAWING: Figure 6

Description

  The present invention relates to, for example, a prediction method of a leveling possible time of concrete such as a concrete slab, a prediction device, and a construction method of concrete.

  Conventionally, when constructing a concrete slab, after placing fresh concrete carried by a mixer from a plant on a formwork, an operation is carried out in which the whole is leveled to a predetermined height. (See, for example, Patent Document 1). The concrete hardens with the passage of time, and after it becomes hard enough for the operator to get on, treatment of bleeding water and ends etc. is carried out, and the surface is repeatedly pressed with a hand-held trowell or scissors.

  This repeated pressing operation is an operation necessary for smoothing and densifying the concrete surface, which greatly affects the quality of the slab. However, the pressing timing is determined by the hardness of the operator touching the concrete surface with a finger, the color of the appearance, the generation of bleeding water, and the like. Therefore, the finish quality such as the smoothness of the slab and the quality such as the fineness of the surface are likely to be influenced by the experience of the worker particularly in the environmental conditions where construction is difficult.

  In the concrete slab casting design plan, the number of workers, the number of workers, the number of working machines, etc. are determined in consideration of conditions such as air temperature, casting area and casting speed on the day of construction. This decision is left to the operator's empirical judgment, and the placement position of concrete is roughly determined by the placement speed. As for the timing of the subsequent pressing work, the operator judges the degree of hardening of the concrete on the day of the construction day by finger touch and visual observation, and proceeds according to the circumstances. Therefore, in the concrete design plan, the number of workers and the construction procedure according to the degree of hardening of the concrete are not planned. The press start time and end time depend on the construction of the construction day, and there are many vague parts as a construction plan.

As a method of grasping the degree of hardening of concrete, there is a penetration resistance test (JIS A 1147: 2007) of JIS. This is a method of determining the penetration resistance value when a mortar obtained by removing coarse aggregate from concrete is used as a test body and a specified penetration needle is pierced vertically. According to this method, as shown in the measurement example of FIG. 1, the measurement results are plotted and the initial development time of the concrete (time until the penetration resistance value becomes 3.4 N / mm ² , for example), the termination time (penetration resistance) The slope A, the intercept B, and the approximate expression can be obtained from the value of, for example, 28.0 N / mm ² ) and the approximate curve of these plots. Workers wear a neta geta and have hardness slightly sinking their feet about 0.5 (N / mm ² ) of penetration resistance empirically, then ride on concrete and remove bleeding water etc. The preparation of the work is started, the pressing work is started from the first flight time, and the work is finished at the closing time.

  However, since this penetration resistance value is obtained by measuring in real time each time the hardening proceeds, it is impossible to predict the pressing timing (the time when the pressing operation can be started) in advance by this method. In addition, the test work is also time-consuming, and there are few cases where it is used for on-site construction management, and there is a problem that the penetration resistance test is mainly intended to acquire data.

JP, 2015-203204, A

  For this reason, there is a need for a technology that can easily grasp the time when the leveling operation can be properly performed (time when the leveling operation is possible) before starting the leveling operation (pressing operation) of the concrete surface. The

  The present invention has been made in view of the above, and is a method of predicting the leveling time of concrete leveling operation time of the leveling operation time which can be easily grasped before the leveling operation of concrete surface is started. It aims to provide a prediction device and a concrete construction method.

  In order to solve the above-mentioned problems and achieve the object, the method for predicting the time of the leveling operation of concrete according to the present invention comprises performing the leveling operation before performing the leveling operation on the surface of concrete under construction It is a method to predict the leveling time that is suitable for work, and the air temperature in the construction time zone and the temperature of concrete are considered to be in correlation, and the predicted air temperature expected in the construction time zone is Obtaining inclination information corresponding to the expected air temperature by applying to the relation between the temperature of concrete and the inclination information of the approximate expression representing the relation between penetration resistance value and elapsed time obtained by the predetermined penetration resistance test which has been grasped; Apply the obtained tilt information to the relationship between tilt information and the time from the water injection time when producing fresh concrete that was grasped in advance to the conductivity decrease time of the concrete The steps of: estimating the conductivity decrease time corresponding to the determined inclination information; estimating the relationship between the penetration resistance value and the elapsed time corresponding to the determined inclination information; and the relationship between the estimated penetration resistance value and the elapsed time And a step of predicting the leveling time of concrete leveling operation from the estimated conductivity lowering time.

  Moreover, the prediction device of the leveling operation possible time of concrete according to the present invention predicts the leveling possible operation time suitable for performing the leveling operation before performing the leveling operation on the surface of the concrete under construction. It is an apparatus for setting the temperature of the construction time zone and the temperature of the concrete, and it is regarded that there is a correlation, and the predicted air temperature expected in the construction time zone is a penetration obtained by a predetermined penetration resistance test grasped in advance A means for determining inclination information corresponding to the predicted air temperature by applying to the relation between the temperature of concrete and the inclination information of an approximate expression representing the relation between the resistance value and the elapsed time, and the obtained inclination information, fresh concrete grasped in advance The conductivity decrease time corresponding to the obtained inclination information by applying the relationship between the time from the water injection time at the time of producing the water to the conductivity decrease time of the concrete and the inclination information The means for estimating, the means for estimating the relationship between penetration resistance value and elapsed time corresponding to the obtained inclination information, the relationship between estimated penetration resistance value and elapsed time, and the leveling of concrete from the estimated conductivity decrease time And means for predicting a workable time.

  Further, in the method of constructing concrete according to the present invention, there are a step of predicting the time when the leveling operation is possible, a step of casting the concrete, and a leveling which is predicted And performing the leveling operation on the surface of the concrete based on the workable period.

  According to the prediction method of the leveling operation possible time of concrete according to the present invention, the leveling operation possible time suitable for performing the leveling operation is predicted before performing the leveling operation on the surface of the concrete under construction The method to determine the temperature of the construction time zone and the temperature of the concrete are correlated, and the predicted air temperature expected in the construction time zone can be obtained by a predetermined penetration resistance test obtained in advance. A step of obtaining inclination information corresponding to the predicted air temperature by applying to the relation between the temperature of concrete and the inclination information of an approximate expression representing the relation between the resistance value and the elapsed time, and the calculated inclination information in advance. The conductivity decrease corresponding to the obtained inclination information by applying to the relation of the inclination information with the time from the water injection time at the time of manufacturing the time to the conductivity decrease time of the concrete The step of estimating time, the step of estimating the relationship between the penetration resistance value and the elapsed time corresponding to the obtained inclination information, the relationship between the estimated penetration resistance value and the elapsed time, and the estimated conductivity decrease time, the concrete Since the step of predicting the leveling possible time is provided, it is possible to easily grasp the leveling possible time before starting the leveling operation of the concrete surface.

  Moreover, according to the prediction device of the leveling operation possible time of concrete according to the present invention, the leveling operation possible time suitable for performing the leveling operation before performing the leveling operation on the surface of the concrete under construction It is an apparatus for predicting the temperature of the construction time zone, and the temperature of the construction time zone is considered to be correlated with the temperature of concrete, and the predicted air temperature expected during the construction time zone is obtained by a predetermined penetration resistance test grasped beforehand. The slope information corresponding to the predicted air temperature is obtained in advance by grasping the slope information corresponding to the predicted air temperature by applying it to the slope information of the approximate expression representing the relation between the penetration resistance value and the elapsed time and the temperature of the concrete. The conductivity low corresponding to the inclination information obtained by applying the relationship between the time from the water injection time when producing fresh concrete to the conductivity decrease time of the concrete and the inclination information From the means for estimating time, the means for estimating the relationship between penetration resistance value and elapsed time corresponding to the obtained inclination information, the relationship between estimated penetration resistance value and elapsed time, and from the estimated conductivity decrease time, concrete Since a means for predicting the leveling possible time is provided, it is possible to easily grasp the leveling possible time before starting the leveling operation of the concrete surface.

  Further, according to the method of constructing concrete according to the present invention, the step of predicting the leveling possible period of time using the above-described method of predicting the leveling possible period of concrete, the step of placing concrete, and the prediction Since the step of performing the leveling operation on the surface of the concrete based on the leveling possible time is provided, it is possible to properly perform the leveling operation based on the predicted leveling possible time, and stable quality The effect of being able to construct the concrete of

FIG. 1 is a view showing a measurement example of a penetration resistance test according to JIS. FIG. 2 is a view showing the relationship between the temperature T of the concrete and the inclination A. As shown in FIG. FIG. 3 is a view showing an example of the time change of the conductivity. FIG. 4 is a diagram showing the relationship between the time t from the water injection time to the conductivity decrease time and the slope A. As shown in FIG. FIG. 5 is a diagram showing the relationship between the penetration resistance value and the elapsed time when the slope A is 56.9. FIG. 6 is a flow chart diagram showing an embodiment of a method of predicting the leveling possible time of concrete according to the present invention. FIG. 7 is an input / output screen view showing an embodiment of the prediction device of the leveling possible time of concrete according to the present invention. FIG. 8 is a diagram showing an example of calculation of elapsed time and penetration time in penetration resistance value. FIG. 9 is a diagram showing a display example of the prediction device based on “expected temperature” and “scheduled water supply time”. FIG. 10 is an input / output screen diagram showing an example of a prediction device of another concrete leveling possible time. FIG. 11 is a view showing a display example of the prediction device based on “water injection time” and “conductivity decrease time”.

  EMBODIMENT OF THE INVENTION Below, the prediction method of the leveling operation possible time of the concrete which concerns on this invention, embodiment of the prediction apparatus, and the construction method of concrete are described in detail based on drawing. The present invention is not limited by the embodiment.

[How to predict the time when concrete can be leveled]
First, an embodiment of a method of predicting the leveling possible time of concrete according to the present invention will be described.

(Basic principle)
First, the basic principle of the present invention will be described.
Generally, the concrete in the setting process is subjected to the penetration resistance test described in, for example, JIS A 1147, and when the penetration resistance value is plotted at each elapsed time, a scatter diagram as shown in FIG. 1 is obtained. From these plots, the relationship between the penetration resistance value P and the elapsed time t can be represented by a logarithmic approximation formula t = A × Ln (P) + B. Here, A is inclination (inclination information) and B is an intercept.

  FIG. 2 illustrates the relationship between the temperature T of the concrete and the slope A. As shown in this figure, it can be seen that the concrete temperature T has a high correlation with the slope A. Therefore, if the predicted air temperature on the day of construction (construction time zone) is obtained, the slope A can be obtained from this figure on the premise that the temperature does not differ significantly from the temperature of the concrete.

On the other hand, when an electrode of a conductivity meter is placed on concrete and the conductivity is measured, the conductivity gradually increases as shown in FIG. 3, but starts decreasing at a certain time (12 in the example of the figure: Around 50). The time when the conductivity starts to decrease is referred to as the conductivity decrease time. The conductivity lowering time is related to the reaction of cement in concrete, and is known to coincide with the time at which a penetration resistance of 0.1 (N / mm ² ) is developed.

  FIG. 4 is a diagram showing the relationship between the time t from the water injection time to the conductivity decrease time and the slope A. As shown in FIG. As shown in this figure, it can be seen that the time t from the water pouring time of concrete (the time when cement and water are mixed in the plant at the time of preparation of fresh concrete) to the conductivity decreasing time has a high correlation with the slope A. That is, if the inclination A is known, the time t from the water injection time to the conductivity decrease time can be obtained.

  For example, assuming that the predicted air temperature on the day of concrete construction is 20 ° C., the inclination A is determined as A = 56.9 by substituting T = 20 into the approximate expression of FIG. From the slope A = 56.9 to the approximate expression in FIG. 4, the time t from the water injection time to the conductivity decrease time is determined to be 188 minutes. Therefore, for example, when the water injection time is set to 9:00, the conductivity decrease time can be obtained as 12:08 after 188 minutes.

FIG. 5 shows the relationship between the penetration resistance value and the elapsed time in the case of the slope A = 56.9. As described above, since the conductivity lowering time coincides with the time when the penetration resistance value becomes 0.1 (N / mm ² ), in this figure, this time is set as the origin (0 minutes). From this figure, it is 13:40 since the penetration resistance value reaches 0.5 (N / mm ² ) from 12:08 to 92 minutes after the conductivity decrease time, and the penetration resistance value of the first flight time is 3. As it is 15:29 after 201 minutes to reach 4 (N / mm ² ) and 17:29 after 321 minutes to reach penetration resistance value 28.0 (N / mm ² ) at termination time It can be asked.

(Specific prediction procedure)
Next, the procedure in the case of predicting the pressing timing at the time of construction of a concrete slab will be described by the prediction method according to the present embodiment.

  As shown in FIG. 6, first, from the predicted air temperature on the day of construction, a slope A is calculated using FIG. 2 (step S1). Next, from the inclination A, the time from the water injection time to the conductivity decrease time is calculated using FIG. 4 (step S2). Next, the water injection time is set to calculate the conductivity decrease time (step S3), and the slope A is used to calculate the relationship between the penetration resistance value and the elapsed time (step S4).

  Next, using the relationship between the calculated penetration resistance value and the elapsed time, the elapsed time is added to the conductivity reduction time to calculate the time at each penetration resistance value (step S5). As a result, it is possible to predict the following work time (time when the work can be done) and time before construction (step S6).

  That is, it is possible to predict the working time such as the time when a person can get on the surface of the concrete slab, the pressing start time, and the pressing end time. The time from the time when a person can get on to the time to start pressing is a time where preparation for removal of bleeding water, repair of the concrete slab end, etc. is possible. The time from the press start time to the press end time is a time when the press work is possible.

  As described above, according to the prediction method of the present embodiment, it is possible to easily predict the pressing timing of the concrete slab before the construction using the predicted air temperature on the day of construction and the like. As a result, it becomes possible to plan the number and arrangement of workers and construction machines suitable for construction, and it is possible to make use of it for construction preparation and construction management. For this reason, a concrete slab of stable quality can be constructed.

[Prediction device for concrete leveling time]
Next, an embodiment of the prediction device of the concrete workable time of concrete according to the present invention will be described.

  The prediction apparatus of the leveling operation possible time of concrete according to the present embodiment embodies the above method of predicting the leveling operation possible time of concrete as an apparatus, and, for example, an input unit, an output unit, a calculation unit, It consists of a display part. The prediction device can be configured, for example, by a computer having a CPU, hardware such as a memory or a display, or software such as a computer program running on the hardware.

  FIG. 7: is an example of the input-output screen of the prediction apparatus of the leveling operation possible time of the concrete based on this Embodiment. A screen as illustrated is displayed on a display unit such as a display. In this screen, an input unit (INPUT) and an output unit (OUTPUT) are arranged.

  The input unit (INPUT) includes a field for inputting the "expected temperature" on the day of construction, and a field for inputting "scheduled water injection time" for mixing cement and water at the time of preparation of fresh concrete. The input values for each column are used in the arithmetic processing of the arithmetic unit.

  The output unit (OUTPUT) has a column for outputting “slope A” and “conductivity decrease time” which are intermediate output items, “time when people can get on” which is final output items, “pressing work start time”, It consists of columns for outputting "pressing work end time", "time to work start", and "time for pressing work available". The calculated value calculated by the arithmetic processing of the arithmetic unit is output to each column.

  When two items of “expected air temperature” and “water injection scheduled time” of the input unit are inputted, the inclination A is calculated by the arithmetic processing of the arithmetic unit, and the conductivity decrease time is calculated. Then, from these calculated values, the “time when a person can ride”, “pressing start time”, “pressing end time”, “time until work start”, and “pressing possible time” are calculated. These calculated values are instantaneously output and displayed in each column of the output unit. Therefore, the user of this prediction apparatus can easily grasp the above-mentioned work time and time through this input / output screen. In the example shown in the figure, the output result is shown when the predicted temperature is 20 ° C. and the scheduled water supply time is 9:00.

(How to calculate the slope A)
Next, a method of calculating the inclination A by the calculation unit will be described.
The calculation unit obtains the slope A from the approximate expression shown in FIG. 2 using the input predicted air temperature on the day of construction. However, it is premised that the concrete temperature T does not differ from the predicted air temperature extremely. For example, when the predicted air temperature is 20 ° C., T = 20 is substituted into the approximate expression of FIG. 2, and 56.9 is calculated as the slope A.

(How to calculate the time from water injection time to conductivity decrease time)
Next, a method of calculating the time from the water injection time to the conductivity decrease time by the calculation unit will be described.
The calculation unit sets the input scheduled water injection time as the water injection time, and obtains the time from the set water injection time to the conductivity decrease time from the approximate expression shown in FIG. 4. For example, when 56.9 is calculated as the slope A as described above, A = 56.9 is substituted in the approximate expression of FIG. 2, and 188 minutes is calculated as the time t from the water injection time to the conductivity decrease time. Be done.

(How to calculate each work time)
Next, a method of calculating each work time by the calculation unit will be described.
The calculation unit obtains each operation time from an approximate expression (t = A × Ln (P) + B) representing the relationship between the penetration resistance value P and the elapsed time t. Here, as described above, since the penetration resistance value P = 0.1 (N / mm ² ) matches the penetration resistance value at the conductivity lowering time, in order to make this time 0 minutes, , P = 0.1 and a value of t = 0 is adopted. In this case, the above approximate expression can be expressed as t = A × (Ln (P) −log (0.1)) = A × (Ln (P) +2.3).

  The calculation unit calculates an elapsed time t and each time of the penetration resistance value P using the above-mentioned approximate expression, and creates a table as shown in FIG. 8, for example. For example, in the case of the slope A = 56.9, the approximate expression is t = 56.9 × (Ln (P) +2.3). As shown in FIG. 8, the penetration resistance value P = x (for example, x = 0.1, 0.2,..., 30.0) is substituted into this approximate expression to correspond to each penetration resistance value x. Calculate the elapsed time t.

  Then, the conductivity decrease time 12: 08 is calculated by adding the time t = 188 minutes from the water injection time already calculated to the conductivity decrease time to the water injection time 9:00. This conductivity decrease time corresponds to an elapsed time of 0 minutes. The time corresponding to each penetration resistance value x is calculated by adding the elapsed time t calculated from the approximate expression to the calculated conductivity decrease time. By doing this, a table as shown in FIG. 8 can be created.

From this figure, since the conductivity decrease time (elapsed time 0 minutes) is 12:08, the penetration resistance value reaches 0.5 (N / mm ² ) at 13:40 after 91 minutes, which is the first occurrence. The penetration resistance value of time 3.4 (N / mm ² ) is reached at 15:29 after 201 minutes, the penetration time of termination time 28.0 (N / mm ² ) is reached after 17 minutes 321 minutes : It turns out that it is 29. The arithmetic unit outputs such time as a calculated value to the output unit. In addition, the calculation unit calculates the time until the start of the work and the pressable work available time from the difference between the respective target times, and outputs the time to the output unit.

  According to the above configuration, only by inputting the two items of "expected temperature" and "scheduled water injection time", "time when people can get on", "time for starting pressing work", "pressing time" before construction of a concrete slab It is possible to instantly obtain the work end time, the time until the work start, and the pressing workable time.

  In addition, before the concrete slab construction day, it is possible to grasp the time when construction preparation and pressing work are possible. As a result, the number of workers and construction machines and preparation for arrangement can be specifically planned, and the work end time can be grasped. In addition, by utilizing this for construction management, it becomes possible to construct a concrete slab of stable quality.

(Modification 1 of prediction device)
Next, a modification of the embodiment of the prediction device of the leveling operation possible time of concrete according to the present invention will be described.

  The prediction device of the leveling operation possible time of concrete according to the above-mentioned embodiment is, as shown in the input / output screen of FIG. 7, a time related to the leveling operation based on the "expected temperature" and the "scheduled water injection time". And time can be predicted before the date of construction.

  However, in this screen display, at a construction site where many mixer cars carry in concrete and cast it as a slab, it may be difficult to grasp at which position of the slab the time for the concrete is.

  Therefore, in the first modification, in order to solve such a problem and to utilize the prediction device as a field management tool, the time related to the leveling operation obtained as shown in FIG. 7 is visually displayed in an easily understandable manner. The present modification 1 will be described below.

  In the first modification, as shown in the input / output screen of FIG. 9, the number of No. 1, No. 2,... Is assigned to separate meshes, so that it is possible to input "expected temperature" and "scheduled water injection time (displayed as water injection time in the figure)" for each mesh. The number of meshes can be set, for example, by the following procedure.

(1) The volume of concrete loaded on one mixer vehicle is divided by the thickness of the planned concrete to obtain the area which can be cast by one mixer vehicle.
(2) The castable length of one mixer car is obtained by dividing the castable area obtained in the above (1) by the casted width of concrete. The placement width of concrete is approximately 2 m from the viewpoint of the operator's ease of construction and management, and the loading capacity of one mixer truck is usually 4.25 m ³ , so for example, the thickness of concrete is 0.25 m In the case of, the casting length is 8.5m.
(3) The number of meshes is set by dividing the length of one side of the site where concrete is to be placed by the placement length of one mixer vehicle. In the example of FIG. 10, the case where the construction range of a rectangular shape is divided | segmented into four meshes in the horizontal direction by planar view is shown.

  Now, when "expected temperature" and "water injection scheduled time" are input to each mesh, the "pressing start time", "pressing end time", and the pressing end time of the mesh are calculated by the calculation processing of the calculation unit and the output display processing of the output unit “Pressing available time” is displayed. In the example of FIG. 9, “water injection scheduled time” is displayed as “water injection time”, “pressing work start time”, “pressing work end time” and “pressing work possible time” are respectively “start time” and “start time” It shows a case where it is displayed as "end time" and "working time". In the upper part of the screen, an "INPUT" key 1, a "+10 min" key 2, a "OUTPUT" key 3 and an "OUTPUT" key 4 are disposed in order from the left. “INPUT” key 1 is an operation key for inputting “expected temperature” and “water injection time” of each mesh, and “+10 min” key 2 is an operation key for automatically adding water injection time of the following mesh for 10 minutes, "OUTPUT" key 3 is an operation key for outputting and displaying "start time" and "end time" of each mesh, and "OUTPUT" key 4 is an operation key for outputting and displaying "working time" of each mesh .

  Further, when a change in air temperature (for example, 25 ° C. → 28 ° C.) can be considered with the passage of time, an expected air temperature (28 ° C.) is input in the corresponding mesh number (for example, mesh No. 12 in the middle). Thereby, each time and working time according to the latest predicted air temperature are displayed.

  Also, if the water injection time is used, the number of mixers per hour can be determined according to the concrete design plan. For example, assuming that six mixer cars per hour are planned to be put on site in FIG. 9, if the water injection time of No. 1 is 8:30, No. 2 to No. 11 are automatically injected at the water injection time. The 10-minute interval is added and each time and working time are displayed on each mesh.

  As described above, according to the first modification, by inputting “expected temperature” and “water injection time (water injection scheduled time)” on the input / output screen as shown in FIG. Can be predicted. For this reason, at the construction site where many mixer cars carry in concrete and place them as slabs, the "pressing start time", "pressing end time", and "pressing work possible" for concrete at any position of the slab Since it becomes possible to visually grasp whether it is "time" in an easy-to-understand manner, construction management on site can be easily performed.

(Modification 2 of prediction device)
The above-mentioned modification 1 is applicable also to the case where the prediction device of the similar input / output screen is displayed in an easily understandable manner.

  As a prediction device of a similar input / output screen, for example, a prediction device of “concrete leveling operation possible time period” proposed by the present patent applicant in the context of the present invention in Japanese Patent Application No. 2017-200254 (currently undisclosed) "Is mentioned. This prediction device measures the conductivity of the concrete under construction, and obtains the conductivity decrease time when the conductivity of the concrete decreases, and when preparing the fresh concrete in which the conductivity decrease time obtained is grasped in advance. The time from the water injection time of mixing cement and water to the conductivity decrease time of concrete, and the relationship of the inclination information of the approximate expression representing the relationship between the penetration resistance value obtained by the predetermined penetration resistance test and the elapsed time, A means for obtaining inclination information corresponding to the determined conductivity lowering time, a means for estimating the relationship between the penetration resistance value and the elapsed time corresponding to the obtained inclination information, a relationship between the estimated penetration resistance value and the elapsed time, and And a means for predicting the leveling time of concrete leveling operation from the conductivity lowering time.

  As a more concrete prediction procedure, while taking a concrete sample and recording water injection time, measurement of conductivity is started. Thereafter, the time from the water injection time to the conductivity decrease time is calculated, the slope A is calculated from a predetermined approximate expression, and the relation between the penetration resistance value and the elapsed time is calculated using the slope A. The time at each penetration resistance value is calculated by adding the elapsed time to the conductivity lowering time using the relationship between the calculated penetration resistance value and the elapsed time. As a result, it becomes possible to predict "pressing start time", "pressing end time", and "time available for pressing" before construction.

  FIG. 10 is an example of an input / output screen of this prediction device. It is a display form similar to FIG. As shown in FIG. 10, this prediction device predicts the time and work time related to the leveling operation before the start of the leveling operation based on the “water injection time” and the “conductivity decrease time”. Also in the case of this screen display, at a construction site where many mixer vehicles carry in concrete, it may be difficult to grasp at which position of the slab the concrete is at the time of concrete. Therefore, in the second modification, as in the first modification, the time relating to the leveling operation is displayed in an easily understandable manner.

  In the second modification, as shown in the input / output screen of FIG. 11, the number of No. 1, No. 2,... Assign to divide the mesh. Then, “water injection time” and “conductivity decrease time” can be input to the mesh obtained by collecting concrete samples from the mixer vehicle. The number of meshes can be set by the same method as that of the first modification described above.

  Although a mixer truck for collecting samples is optional, it is usually easier to understand if it is collected from the first unit (No. 1 in FIG. 11). In No. 2 and later, the start time (pressing start time) and the end time (pressing end time) are automatically added according to the number of mixer cars per hour. In FIG. 11, the results of automatically adding the water injection time by 10 minutes are displayed from No. 2 to No. 4. On the other hand, for example, when collecting a sample from No. 3 on the way, it can be displayed by subtracting 10 minutes from each working time of No. 1 and No. 2.

  In addition, when it is possible to collect the sample again during the placement and measure the conductivity decrease time (for example, sample collection from No. 5), each operation time added 10 minutes again with No. 6 and later in FIG. Can be displayed.

  In the example of FIG. 11, the "INPUT" key 1, the "+10 min" key 2, the "OUTPUT" key 3 and the "OUTPUT" key 4 are arranged in order from the left at the top of the screen. "INPUT" key 1 is an operation key for inputting "water injection time" and "conductivity decrease time" of each mesh, and "+10 min" key 2 is an operation for automatically adding water injection time of the subsequent mesh for 10 minutes The key, "OUTPUT" key 3 are operation keys for outputting and displaying the "start time" and "end time" of each mesh, and the "OUTPUT" key 4 is an operation key for outputting and displaying the "working time" of each mesh It is.

  As described above, according to the second modification, each time and the operation time are predicted for each mesh by inputting “water injection time” and “conductivity decrease time” on the input / output screen as shown in FIG. be able to. For this reason, at the construction site where many mixer cars carry in concrete and place them as slabs, the "pressing start time", "pressing end time", and "pressing work possible" for concrete at any position of the slab Since it becomes possible to visually grasp whether it is "time" in an easy-to-understand manner, construction management on site can be easily performed.

[Concrete construction method]
Next, an embodiment of a method of constructing concrete according to the present invention will be described by taking a case of constructing a concrete slab as an example.

  First, before constructing a concrete slab, the leveling operation possible time is predicted using the above-described prediction method of the leveling operation possible time of concrete. Thereby, it becomes possible to grasp "time when a person can get on", "pressing start time", "pressing end time", "time until start of work", and "time available for holding work" before construction.

  Next, fresh concrete is cast on a form and a concrete slab is constructed. Then, when it is "time when people can get on", a worker gets on the hardened concrete slab and carries out work such as treatment of bleeding water and ends. This work is planned to be completed within the "time to work start". After that, when the “pressing start time” is reached, the surface is repeatedly pressed with a hand-held trowell or a hook. This work is performed in a planned manner so as to finish within the “pressing work possible time”, and the work is finished at “the pressing work end time”.

  As described above, according to the present embodiment, it is possible to properly perform the leveling operation on the surface of the concrete slab based on the leveling possible time predicted before the construction. Thereby, a concrete slab of stable quality can be constructed.

  As explained above, according to the prediction method of the leveling operation possible time of concrete according to the present invention, the leveling suitable for performing the leveling operation before performing the leveling operation on the surface of the concrete under construction It is a method to predict the workable period, and it is considered that the air temperature in the construction time zone and the temperature of the concrete are in a correlation, and the predicted air temperature expected in the construction time zone is a predetermined penetration previously grasped A step of obtaining inclination information corresponding to the predicted air temperature by applying to the relation of inclination temperature of an approximate expression representing the relation between penetration resistance value and elapsed time obtained by resistance test and the temperature of concrete, and the obtained inclination information Inclination information obtained by applying the relationship between the time from water injection time when producing fresh concrete that was grasped in advance to the conductivity decrease time of concrete and the inclination information The step of estimating the corresponding conductivity decrease time, the step of estimating the relationship between the penetration resistance value and the elapsed time corresponding to the obtained inclination information, the relationship between the estimated penetration resistance value and the elapsed time, and the estimated conductivity decrease Since the step of predicting the leveling time of concrete can be predicted from the time, it is possible to easily grasp the leveling possible time before starting the leveling operation of the concrete surface.

  Moreover, according to the prediction device of the leveling operation possible time of concrete according to the present invention, the leveling operation possible time suitable for performing the leveling operation before performing the leveling operation on the surface of the concrete under construction It is an apparatus for predicting the temperature of the construction time zone, and the temperature of the construction time zone is considered to be correlated with the temperature of concrete, and the predicted air temperature expected during the construction time zone is obtained by a predetermined penetration resistance test grasped beforehand. The slope information corresponding to the predicted air temperature is obtained in advance by grasping the slope information corresponding to the predicted air temperature by applying it to the slope information of the approximate expression representing the relation between the penetration resistance value and the elapsed time and the temperature of the concrete. The conductivity low corresponding to the inclination information obtained by applying the relationship between the time from the water injection time when producing fresh concrete to the conductivity decrease time of the concrete and the inclination information From the means for estimating time, the means for estimating the relationship between penetration resistance value and elapsed time corresponding to the obtained inclination information, the relationship between estimated penetration resistance value and elapsed time, and from the estimated conductivity decrease time, concrete Since it is equipped with means for predicting the leveling possible time, it is possible to easily grasp the leveling possible time before starting the leveling operation of the concrete surface.

  Further, according to the method of constructing concrete according to the present invention, the step of predicting the leveling possible period of time using the above-described method of predicting the leveling possible period of concrete, the step of placing concrete, and the prediction Since the step of performing the leveling operation on the surface of the concrete based on the leveling possible time is provided, it is possible to properly perform the leveling operation based on the predicted leveling possible time, and stable quality Concrete can be constructed.

  As described above, the method for predicting the leveling time of concrete leveling operation according to the present invention, the prediction device and the method for constructing concrete are useful for the construction of a concrete slab, and in particular, the start timing of leveling operation for concrete slab Suitable for prediction.

Claims (3)

It is a method for predicting a time suitable for performing a leveling operation before performing the leveling operation on the surface of concrete under construction.
Assuming that the air temperature in the construction time zone and the temperature of the concrete are correlated, the predicted air temperature predicted in the construction time zone is the relationship between the penetration resistance value obtained by a predetermined penetration resistance test grasped beforehand and the elapsed time Obtaining inclination information corresponding to the predicted air temperature by applying the relation between the inclination information of the approximate expression to be expressed and the temperature of the concrete;
Conductivity decrease corresponding to the obtained inclination information by applying the obtained inclination information to the relationship between the time from the time of water injection at the time of preparing fresh concrete to the time when conductivity of the concrete decreases and the inclination information Estimating the time,
Estimating a relationship between penetration resistance value and elapsed time corresponding to the obtained inclination information;
And a step of predicting the leveling time of the concrete from the relationship between the estimated penetration resistance value and the elapsed time and the estimated conductivity decrease time, and a method of predicting the leveling time of the leveling operation of concrete. An apparatus for predicting a time suitable for performing a leveling operation before performing a leveling operation on the surface of concrete under construction,
Assuming that the air temperature in the construction time zone and the temperature of the concrete are correlated, the predicted air temperature predicted in the construction time zone is the relationship between the penetration resistance value obtained by a predetermined penetration resistance test grasped beforehand and the elapsed time A means for obtaining inclination information corresponding to the predicted air temperature by applying the relation between the inclination information of the approximate expression to be expressed and the temperature of the concrete;
Conductivity decrease corresponding to the obtained inclination information by applying the obtained inclination information to the relationship between the time from the time of water injection at the time of preparing fresh concrete to the time when conductivity of the concrete decreases and the inclination information A means for estimating the time of day;
A means for estimating the relationship between penetration resistance value and elapsed time corresponding to the obtained inclination information;
A device for predicting the leveling operation possible time of concrete, comprising: means for predicting the leveling operation possible time of concrete from the estimated relationship between penetration resistance value and elapsed time and estimated conductivity decreasing time. Predicting the possible workable period using the method of predicting the possible workable time of concrete according to claim 1;
Step of placing concrete,
And performing a leveling operation on the surface of the concrete on the basis of the predicted leveling time.

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