JP2020176483A - Concrete construction management method and construction management system - Google Patents

Abstract

To provide a concrete construction management method and a construction management system which can acquire information necessary for construction management without movement of a construction manager.SOLUTION: A construction management method of concrete placed using concrete supply means includes the steps of: photographing a state when concrete is placed and acquiring temporarily sequential images; extracting information on concrete supply means, a placing range and a placing time from the acquired image; and recording the extracted information.SELECTED DRAWING: Figure 4

Description

The present invention relates to a construction management method and a construction management system for concrete such as a concrete slab.

As shown in FIG. 5, the concrete slab is generally constructed through the operations of mixing, placing concrete, leveling, and pressing. In this construction management, it is extremely important to obtain information on the range of the site where the concrete discharged from the mixer truck was placed. It takes time to place concrete. For example, if a mixer truck (loading capacity 4.25 m ³ ) is placed at a pace of 10 units per hour (1 unit in 6 minutes), for example, the slab thickness is 150 mm. In the case of, the casting range will be expanded at about 280 m ² / hour. If the concrete casting design on the day is 1000 m ² , it takes about 3.6 hours to finish all the concrete casting, and there is a time difference of nearly 4 hours between the first mixer truck and the last 36th mixer truck.

When the concrete hardens after a few hours, people start to work on the concrete or start pressing work using a machine from the early stage of hardening. The hardening rate of concrete depends on the composition and the temperature of the concrete on the day, but in the past, people have empirically grasped the timing of construction by visual inspection or touching the work. However, now that the shortage of human resources and experience of workers has become apparent, there are cases where problems such as peeling and blistering occur on the concrete surface after hardening due to incorrect construction timing. Examples of the method for grasping the hardening time of concrete include a setting test using concrete collected from a first mixer truck and a hardening prediction method using conductivity proposed by the present patent applicant (for example, a patent). (Refer to Documents 1 and 2), etc., and the number of samples that can be collected is usually about 2 to 3 in consideration of the labor of work.

As described above, in order to manage the construction of the entire slab, it is necessary to know which mixer truck has placed concrete in what range. Conventionally, as shown in FIG. 6, the construction manager visually confirms the number of mixer trucks and the concrete casting range discharged by the mixer trucks, and records them with handwritten memos or the like. However, since the site when placing concrete is complicated and mixer trucks pass through it, we want to avoid the movement of people as much as possible from the viewpoint of safety. In addition, since there is no mark on the concrete after casting, if the construction record is overlooked, there is no way to check it later and there is a risk that there will be no data. There is also a method of recording the construction status and recording it in a moving image format, but there is a problem that continuous recording does not remain because it is necessary to stop recording in order to check retroactively during recording.

On the other hand, as a conventional technique related to concrete construction management, for example, those shown in Patent Documents 3 to 5 are known. Patent Document 3 identifies a mesh being cast from a video camera image of a concrete casting site, and manages the elapsed time from the completion of casting for each mesh. Patent Document 4 displays a driving marking diagram or the like at a driving site on a touch panel. Patent Document 5 acquires shape data of cast concrete with a shape sensor and displays a concrete driving area and the like.

Japanese Patent Application No. 2017-20254 (Unpublished at this time) Japanese Patent Application No. 2017-20255 (unpublished at this time) Japanese Unexamined Patent Publication No. 2011-202383 Japanese Unexamined Patent Publication No. 2016-204897 Japanese Unexamined Patent Publication No. 2014-114638

In the above concrete slab construction, the technology that allows the construction manager to accurately record the number of mixer trucks, concrete placement range and time required for construction management at a safe position without moving inside the site. Was sought.

The present invention has been made in view of the above, and an object of the present invention is to provide a concrete construction management method and a construction management system capable of acquiring information necessary for construction management without the construction manager moving. ..

In order to solve the above-mentioned problems and achieve the object, the concrete construction management method according to the present invention is a concrete construction management method for placing concrete using a concrete supply means, and is a situation at the time of concrete placement. It is provided with a step of taking a picture of the concrete and acquiring a time-continuous image, a step of extracting information on the concrete supply means, the casting range and the casting time from the acquired image, and a step of recording the extracted information. It is characterized by.

In addition, the other concrete construction management method according to the present invention includes a step of predicting a work range or work time during which leveling work or pressing work can be performed on the concrete surface based on the extracted information in the above-mentioned invention. , A step of performing leveling work or pressing work based on a predicted work range or work time.

Further, the concrete construction management system according to the present invention is a concrete construction management system that is placed using a concrete supply means, and captures the situation at the time of concrete placement to acquire time-continuous images. It is characterized by including an image acquisition means for extracting concrete, an extraction means for extracting information on a concrete supply means, a casting range and a casting time from the acquired image, and a recording means for recording the extracted information.

Further, the other concrete construction management system according to the present invention is a predicting means for predicting the work range or work time during which the leveling work or the pressing work on the concrete surface is possible based on the extracted information in the above-mentioned invention. It is characterized by further providing.

According to the concrete construction management method according to the present invention, it is a concrete construction management method of placing concrete using a concrete supply means, and a situation at the time of placing concrete is photographed to acquire a continuous image in time. Since it is provided with a step of extracting information on the concrete supply means, the casting range and the casting time from the acquired image, and a step of recording the extracted information, the construction manager can manage the construction without moving. It has the effect of being able to obtain the necessary information.

Further, according to another concrete construction management method according to the present invention, it is predicted that the step is to predict the work range or work time during which the leveling work or the pressing work can be performed on the concrete surface based on the extracted information. Since the step of performing the leveling work or the pressing work is further provided based on the work range or the work time, the leveling work or the pressing work can be performed properly, and concrete of stable quality can be constructed. It plays the effect.

Further, according to the concrete construction management system according to the present invention, the concrete construction management system is placed by using the concrete supply means, and the situation at the time of concrete placement is photographed and continuously images in time. Since the construction manager is provided with an image acquisition means for acquiring the image, an extraction means for extracting information on the concrete supply means, the casting range and the casting time from the acquired image, and a recording means for recording the extracted information, the construction manager can move. It has the effect of being able to acquire the information necessary for construction management without having to do it.

Further, according to another concrete construction management system according to the present invention, a predicting means for predicting a work range or a work time during which a leveling work or a pressing work can be performed on a concrete surface is further provided based on the extracted information. Therefore, it is possible to properly perform the leveling work or the pressing work based on the predicted work range or work time, and it is possible to construct concrete of stable quality.

FIG. 1 is a schematic configuration diagram showing an embodiment of a concrete construction management system according to the present invention. FIG. 2 is a diagram showing a recording example of the number of mixer trucks, the concrete casting range / time, and the workable time. FIG. 3 is a diagram showing an example of the relationship between the penetration resistance value and time for each concrete temperature. FIG. 4 is a schematic procedure diagram to which the concrete construction management method according to the present invention is applied. FIG. 5 is an explanatory view of a conventional concrete slab construction method. FIG. 6 is a diagram showing a recording example (number of mixer trucks, time, and casting range) at the time of conventional concrete casting.

Hereinafter, the concrete construction management method and the embodiment of the construction management system according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment.

As shown in FIG. 1, the concrete construction management system 10 according to the embodiment of the present invention includes a video camera 12 as an image acquisition means, a recording device 14 as a recording means, and a monitor 16 as a display means. Be prepared.

The video camera 12 is installed at a position where the entire area where concrete is cast can be photographed, and for example, a digital video camera or the like capable of photographing a moving image is used. The video camera 12 records temporally continuous images while the concrete is being poured, and acquires moving image data with a recording time. It is preferable that the video camera 12 is installed diagonally upward and slightly away from the casting site so that the captured image is flat. If one video camera 12 cannot capture the entire range, a plurality of video cameras 12 may be installed at different positions so that the entire range can be captured. The moving image data acquired by the video camera 12 is recorded in the recording device 14 in real time via a wired or wireless communication line, and can be displayed on the monitor 16 through the recording device 14.

The recording device 14 may be any device capable of so-called "chase playback" in which the recorded video data is played back on the monitor 16 while the video data is being recorded. For example, a video used for television recording / playback at home or the like. It is preferable because the deck is relatively inexpensive and easy to handle. The monitor 16 is for displaying moving image data.

If the construction manager (or worker) reproduces the moving image data recorded in the recording device 14 as necessary, the construction manager can visually check the situation at the time of placing from the image displayed on the monitor 16. it can. As a result, the construction manager can accurately record the number of mixer trucks (concrete supply means), the concrete casting range, and the concrete casting time in the construction record 18. With this method, the construction manager can check back to the concrete placing start time as needed without moving to the concrete placing place. In addition, the number of mixer trucks, the concrete placement range and the placement time can be easily and surely grasped, and continuous moving image recording can be recorded. The number of mixer trucks, the concrete casting range, and the concrete casting time may be visually extracted by the construction manager from the monitor 16 and recorded in the construction record 18, or a computer (extraction means) (not shown). It may be extracted by using the image analysis processing by, and this may be recorded in the construction record 18.

For example, a marker is attached to the tip of a mixer truck or a hose from which concrete is discharged, and markers are placed at key points around the casting range (for example, four corners in the case of a rectangular range in a plan view) to make concrete. To place. This situation is photographed by the video camera 12, the video of the acquired moving image data is subdivided into meshes by image analysis processing of a computer, and analysis is performed for each mesh to extract markers. The mixer truck can be identified by extracting the markers attached to the mixer truck or the like. By counting the display time of the extracted markers, it is possible to grasp the concrete placing time. By extracting the markers around the casting range, the concrete casting range can be grasped. The marker may be configured by a light emitting means such as a light bulb or a light emitting diode that can be recognized by the video camera 12, and may be a marker whose lighting state can be switched by an operation of a casting worker or the like. The lighting state of the marker may be switched from off to on at the start of casting and from on to off at the completion of casting, for example.

As a result, the construction record 18 records the exact number of mixer trucks, the concrete casting range and the casting time by each mixer truck. If the workable time (workable time) obtained from the condensation test or the predicted hardening time of concrete is added to this, the timing when a person gets on the concrete, the timing when the disc starts to be rolled out, and the riding trowell are used. It is possible to accurately grasp the start and end timings of the existing concrete work (leveling work or pressing work). FIG. 2 shows an example of the grasped workable range and time.

As a method for predicting the workable time, a method using a concrete coagulation test collected from a mixer truck or a method described in Patent Document 1 or Patent Document 2 below can be used.

(Method of Patent Document 1)
The method of Patent Document 1 is a method for predicting a suitable leveling work possible time for performing the leveling work before performing the leveling work on the surface of the concrete under construction, and is a method during the construction. The step of measuring the conductivity of concrete and obtaining the time of decrease in conductivity, and the time from the time of water injection when producing fresh concrete, which is grasped in advance, to the time of decrease in conductivity of concrete, By applying to 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, the step of obtaining the inclination information corresponding to the obtained conductivity decrease time and the obtained inclination information The step of estimating the relationship between the penetration resistance value and the elapsed time corresponding to the above, the step of predicting the time when the concrete leveling work is possible from the relationship between the estimated penetration resistance value and the elapsed time and the obtained conductivity decrease time. To prepare. As a result, it is possible to easily grasp the time when the leveling work is possible before starting the leveling work on the concrete surface.

As a more specific method, first, a concrete sample is taken and the water injection time is recorded. Next, a conductivity meter is installed on the collected concrete sample to start measuring the conductivity. Next, the time of decrease in conductivity is recorded, the time from the time of water injection to the time of decrease in conductivity is calculated, and the relationship between the penetration resistance value and the elapsed time is calculated. Next, the time at each penetration resistance value is calculated by adding the elapsed time to the conductivity decrease time using the calculated relationship between the penetration resistance value and the elapsed time. This makes it possible to predict the following work times and times before construction. That is, it is possible to predict the working time such as the time when a person can get on the concrete slab surface, the presser start time, and the presser end time. The time from the time when a person can get on to the time when the presser foot starts is the time when preparations such as bleeding water removal and repair of the concrete slab end can be performed. The time from the presser start time to the presser end time is the time during which the presser operation can be performed.

(Method of Patent Document 2)
The method of Patent Document 2 is a method for predicting a suitable leveling work possible time for performing the leveling work before performing the leveling work on the concrete surface during construction, and is a method for predicting a suitable leveling work time zone. Approximate formula that expresses the relationship between the penetration resistance value and the elapsed time obtained by a predetermined penetration resistance test grasped in advance, assuming that the temperature of concrete and the temperature of concrete are correlated with each other and the expected temperature during construction time. By applying the relationship between the inclination information and the temperature of the concrete, the step of obtaining the inclination information corresponding to the expected temperature and the obtained inclination information can be obtained from the water injection time when producing the fresh concrete grasped in advance. By applying the relationship between the time to the rate decrease time and the inclination information, the step of estimating the conductivity decrease time corresponding to the obtained inclination information and the relationship between the penetration resistance value corresponding to the obtained inclination information and the elapsed time can be obtained. It includes a step of estimating, a step of predicting the concrete leveling work possible time from the relationship between the estimated penetration resistance value and the elapsed time, and the estimated time of decrease in conductivity. As a result, it is possible to easily grasp the time when the leveling work is possible before starting the leveling work on the concrete surface.

As a more specific method, first, the time from the water injection time to the conductivity reduction time is calculated from the expected temperature on the day of construction. Next, the water injection time is set, the conductivity reduction time is calculated, and the relationship between the penetration resistance value and the elapsed time is calculated. Next, the time at each penetration resistance value is calculated by adding the elapsed time to the conductivity decrease time using the calculated relationship between the penetration resistance value and the elapsed time. This makes it possible to predict the following work times and times before construction. That is, it is possible to predict the working time such as the time when a person can get on the concrete slab surface, the presser start time, and the presser end time. The time from the time when a person can get on to the time when the presser foot starts is the time when preparations such as bleeding water removal and repair of the concrete slab end can be performed. The time from the presser start time to the presser end time is the time during which the presser operation can be performed.

<Example>
As mentioned above, for example, when concrete is installed at a pace of 4.25 m ³ and slab thickness is 150 mm per mixer truck and 10 units per hour (1 unit in 6 minutes), about 28 m ² per unit. Concrete will spread over the area of. When the work of shaving and pressing is performed by a machine such as a riding type trowell, the work speed is faster than the concrete placing speed, so it is efficient and desirable to work on a certain area at the same time.

FIG. 3 is an example of the concrete setting test result. As shown in this figure, the hardening rate changes depending on the temperature of the concrete. The timing of mashing is an important point because if the timing is too early, the disk of the machine will sink into the concrete, and if it is too late, the concrete surface will harden and the mashing work will not be possible. In the setting test or the predicted hardening time of concrete, the penetration resistance value is 1.9 (N / mm ² ). Assuming that the degree of hardening of concrete that can be roughened is up to 2.5 (N / mm ² ) in penetration resistance value, it is up to 25 minutes at 11 ° C, 12 minutes at 20 ° C, and 6 minutes at 32 ° C. It becomes. Therefore, in order to perform the work in a cohesive area, the temperature is 11 ° C for 4 units (112m ² ), 20 ° C for 2 units (56m ² ), 32 ° C for 1 unit (28m ² ), and so on. It is possible to specifically specify the construction range that has been settled by.

Next, the procedure of the method of predicting the timing of the pressing work at the time of concrete slab construction by applying the present invention will be described.

As shown in FIG. 4, first, in step S1, the video camera 12 is rotated and recorded on the recording device 14. In the next step S2, the number of mixer trucks, the casting range, and the casting time are retroactively confirmed as necessary by using the recording device 14 and the monitor 16. In the next step S3, the confirmed contents are recorded in the concrete construction record 18.

On the other hand, in step S4, a sample is taken from the concrete to be cast. In the next step S5, the expected curing time by the condensation test or the conductivity is calculated.

After the completion of the above steps S3 and S5, the process proceeds to the next step S6, the workable range and the work time (workable time) are grasped, and based on this, the worker is given an instruction on the timing of the pressing work. To do. In the next step S7, the worker finishes the work at an appropriate timing.

According to the present embodiment, in the construction of the concrete slab, the number of mixer trucks and the concrete placement, which are the information necessary for the construction management, are in a relatively safe position without the construction manager moving in the site. The range and casting time can be recorded accurately. In addition, by combining it with the condensation test of concrete or the predicted curing time based on the conductivity, it is possible to grasp the workable range and work time of the shaving and pressing work. Therefore, it is possible to accurately instruct the worker in the workable range and the work time.

As described above, according to the concrete construction management method according to the present invention, it is a concrete construction management method of placing concrete using a concrete supply means, and the situation at the time of placing concrete is photographed and timely. The construction manager moves because it includes a step of acquiring a continuous image, a step of extracting information on the concrete supply means, the casting range and the casting time from the acquired image, and a step of recording the extracted information. Information necessary for construction management can be obtained without doing so.

Further, according to another concrete construction management method according to the present invention, it is predicted that the step is to predict the work range or work time during which the leveling work or the pressing work can be performed on the concrete surface based on the extracted information. Since the step of performing the leveling work or the pressing work is further provided based on the work range or the work time, the leveling work or the pressing work can be performed properly, and concrete of stable quality can be constructed. ..

Further, according to the concrete construction management system according to the present invention, the concrete construction management system is placed by using the concrete supply means, and the situation at the time of concrete placement is photographed and continuously images in time. Since the construction manager is provided with an image acquisition means for acquiring the image, an extraction means for extracting information on the concrete supply means, the casting range and the casting time from the acquired image, and a recording means for recording the extracted information, the construction manager can move. Information necessary for construction management can be obtained without doing so.

Further, according to another concrete construction management system according to the present invention, a predicting means for predicting a work range or a work time during which a leveling work or a pressing work can be performed on a concrete surface is further provided based on the extracted information. Therefore, it is possible to properly perform the leveling work or the pressing work based on the predicted work range or work time, and it is possible to construct concrete of stable quality.

As described above, the concrete construction management method and the construction management system according to the present invention are useful for the construction management of concrete such as concrete slabs, and in particular, the information necessary for the construction management without the construction manager moving. Suitable for getting.

10 Concrete construction management system 12 Video camera (image acquisition means)
14 Recording device (recording means)
16 monitor 18 construction record

Claims (4)

It is a construction management method for concrete that is cast using concrete supply means.
Record the step of capturing the situation at the time of concrete placing and acquiring a time-continuous image, the step of extracting information on the concrete supply means, the placing range and the placing time from the acquired image, and the extracted information. A concrete construction management method characterized by having steps to be performed. Based on the extracted information, the step of predicting the work range or work time during which the leveling work or pressing work can be performed on the concrete surface, and the leveling work or pressing work based on the predicted work range or work time. The concrete construction management method according to claim 1, further comprising a step. A concrete construction management system that is cast using concrete supply means.
An image acquisition means for capturing a situation at the time of concrete placement and acquiring a time-continuous image, and an extraction means for extracting information on the concrete supply means, the placement range, and the placement time from the acquired images were extracted. A concrete construction management system characterized by being provided with a recording means for recording information. The concrete construction management system according to claim 3, further comprising a predicting means for predicting a work range or a work time at which a leveling work or a pressing work can be performed on a concrete surface based on the extracted information.