JP2012002036A - Placing joint time interval calculation device, placing joint time interval calculation method and placing joint time interval calculation program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide support for preventing a cold joint of concrete.SOLUTION: The device comprises: receiving input data on dimensions of a building frame constructed by layering a plurality of concrete blocks including a thickness of the building frame, the number of concrete block layers in a vertical direction of the building frame and a height of each concrete block layer; receiving input data on a length of the building frame in a horizontal direction and the number of partitions of the concrete blocks in the building frame in the horizontal direction; receiving input data on a concrete placing speed of a pump; receiving input data on an order of placing concrete for each of the concrete blocks; calculating a volume of concrete required per concrete block based on the thickness of the building frame, the height of each of the concrete block layers, the length of the building frame in the horizontal direction and the number of the partitions; calculating a length of time required for placing concrete per concrete block based on the calculated concrete volume and the concrete placing speed of the pump; calculating a placing joint time interval between a specific concrete block and other concrete blocks contacting the specific concrete block based on the calculated length of time required for placing concrete per concrete block and the order of placing concrete; and outputting the results.

Description

  The present invention relates to a technique that assists in preventing cold joints in concrete.

  For example, in the concrete placement on the same day when constructing a concrete structure, the concrete is piled up in multiple layers. When forming a skeleton by stacking multiple layers of concrete in this way, if the concrete is placed after an appropriate time interval, the concrete that has started to harden and the concrete that has been piled up later will not be integrated, resulting in an inconvenience. There may be a cold joint that produces a continuous surface. Such a cold joint is a structural weak part, and the overlapped part is raised on the concrete surface and the appearance is impaired. In view of this, Patent Documents 1 and 2 propose techniques for repairing concrete with respect to a cold joint to improve the strength reduction of the frame or to reduce aesthetic problems.

JP 2001-140595 A JP 2001-248280 A

  However, it is difficult to completely repair the decrease in the strength of the concrete in which the cold joint has occurred, and it is desirable to prevent the occurrence of the cold joint in the first place because the repair requires considerable cost. For this purpose, it is necessary to perform the placement so that the overlapping time interval for each layer falls within a time interval that does not cause a cold joint. Here, how much the stacking time interval according to the thickness of the casing, the length and height of the block, the moving time of the pump, and the like is manually calculated by a construction worker or the like. Then, it is determined by the installer whether or not the overlapping time interval calculated by manual calculation is a time interval that does not cause a cold joint. In this case, not only labor and time are required to calculate an appropriate overlapping time interval, but also an artificial calculation error may occur. It is desirable that such a stacking time interval is easy to understand for an installer or the like, and can be calculated without any mistake and quickly.

  The present invention has been made in view of such a situation, and calculates a concrete stacking time interval for each block when stacking a plurality of blocks of concrete to form a frame to prevent a cold joint of the concrete. The present invention relates to an overlap time interval calculation device, an overlap time interval calculation method, and an overlap time interval calculation program.

  In order to solve the above-described problems, the present invention provides a frame size including the thickness of a frame formed by stacking a plurality of blocks of concrete, the number of block layers in the vertical direction of the frame, and the height of each layer. The housing dimension input section that receives the input of the housing, the length of the housing in the horizontal direction, the section dimension input section that receives the input of the number of block sections in the horizontal direction of the housing, and the input of the casting speed of the pump for pouring the concrete A casting speed input section for receiving the concrete, a casting order input section for receiving input of the concrete placing order for each block, the thickness of the frame, the height of each layer, the horizontal length of the chassis, and the number of sections Based on the concrete amount calculation unit for calculating the concrete amount per block, the calculated concrete amount per block, and the pumping speed Overlay for calculating a time interval between a block and another block in contact with the block based on a required time calculation unit for calculating a required time for placement per block, a required time for placement, and a placement order. An overlap time interval calculation device comprising: a time interval calculation unit; and an output unit that outputs an overlap time interval.

  In addition, the present invention is characterized in that the above-described output unit outputs an image in which a plurality of blocks are sequentially displayed at the positions of the blocks in the frame in accordance with the placement order.

  Further, the present invention is characterized in that the frame is a tunnel, and the above-described overlap time interval calculation unit calculates the overlap time interval with the ceiling portion of the tunnel as one block regardless of the number of sections.

  Further, according to the present invention, the above-described overlap time interval calculation apparatus is configured such that the overlap time interval threshold value determined to such an extent that a cold joint between blocks does not occur and the overlap time calculated by the overlap time interval calculation unit. A determination unit that compares the interval and outputs an alarm when the overlapping time interval calculated by the time interval calculation unit exceeds a threshold is provided.

  In addition, the present invention accepts and stores inputs of a cabinet size including a thickness of a cabinet formed by stacking a plurality of blocks of concrete, the number of blocks in the vertical direction of the cabinet, and the height of each layer. A step of receiving and storing an input of a horizontal length of the frame and a number of block sections in the horizontal direction of the frame; and a step of receiving and storing an input of a setting speed of a pump for pouring concrete; Accepting and storing the input of the concrete placement order for each block, the thickness of the frame, the height of each layer, the horizontal length of the frame, and the number of compartments per block Based on the step of calculating the amount, the calculated concrete amount per block, and the pumping speed, the required placement per block A step of calculating an interval, a step of calculating a stacking time interval between a block and another block in contact with the block based on a placement time and a placing order, and a step of outputting a stacking time interval And a method for calculating the overlap time interval.

  Further, the present invention provides a housing size including a thickness of a housing formed by stacking a plurality of blocks of concrete in a computer of a stacking time interval calculation device, the number of layers of blocks in the vertical direction of the housing, and each layer. Receiving and storing the input of the height of the housing, the step of receiving and storing the input of the horizontal length of the housing and the number of block sections in the horizontal direction of the housing, and the placement of the pump for placing the concrete Steps for accepting and storing speed input, steps for accepting and storing input of concrete placement order for each block, frame thickness, height for each layer, horizontal length of the frame, and number of sections Based on the above, the step of calculating the concrete amount per block, the calculated concrete amount per block, and the pumping speed The step of calculating the required driving time per block based on the above, the step of calculating the overlapping time interval between the block and the other blocks in contact with the block based on the required driving time and the driving order And a step of outputting the overlapping time interval.

  As described above, according to the present invention, the size of the frame including the thickness of the frame formed by stacking a plurality of blocks of concrete, the number of blocks in the vertical direction of the frame, and the height of each layer Accept the input, accept the input of the horizontal length of the frame and the number of blocks in the horizontal direction of the frame, accept the input of the pumping speed, accept the input of the concrete placing order for each block, Calculate the amount of concrete per block based on the thickness of the frame, the height of each layer, the length of the frame in the horizontal direction, and the number of compartments. Based on the setting speed, the time required for placing per block is calculated. Based on the time required for placing and the order of placing, the block and other blocks that touch the block are calculated. Since superimposed so as to output the calculated time interval, it is possible to calculate the droplet overlapping time interval of the concrete for each block in forming the precursor by overstruck concrete multiple blocks. Thereby, for example, the installer can know an appropriate stacking time interval according to the size of the concrete body to be placed, and compares this stacking time interval with the concrete hardening time. Thus, it is possible to formulate a stacking time interval that does not cause a cold joint.

It is a block diagram which shows the structural example of the overlapping time interval calculation apparatus by one Embodiment of this invention. It is a figure which shows the example of a screen displayed on the overlapping time interval calculation apparatus by one Embodiment of this invention. It is a figure which shows the example of the housing made into the calculation object of the overlap time interval by the overlap time interval calculation apparatus by one Embodiment of this invention. It is a figure which shows the example of the cross-sectional area of the block calculated by the overlapping time interval calculation apparatus by one Embodiment of this invention. It is a figure which shows the example of a screen displayed on the overlapping time interval calculation apparatus by one Embodiment of this invention. It is a figure which shows the example of a screen displayed on the overlapping time interval calculation apparatus by one Embodiment of this invention. It is a figure which shows the example of data of the result file which the overlapping time interval calculation apparatus by one Embodiment of this invention outputs. It is a flowchart which shows the operation example of the overlapping time interval calculation apparatus by one Embodiment of this invention.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing the configuration of the overlapping time interval calculation apparatus 100 according to this embodiment. The stacking time interval calculating device 100 is a computer device that calculates a stacking time interval of concrete when a concrete body is formed by stacking a plurality of blocks of concrete. A so-called PC (personal computer) or the like can be applied to the overlapping time interval calculation apparatus 100. The overlapping time interval calculation device 100 includes an output unit 101, a body size input unit 102, a section size input unit 103, a placement speed input unit 104, a placement order input unit 105, and a concrete amount calculation unit 106. The required time calculation unit 107, the overlapping time interval calculation unit 108, the output control unit 109, and the determination unit 110 are provided.

  The output unit 101 is a display that outputs and displays an information input screen and an information output screen. For example, FIG. 2 is a diagram illustrating an example of a screen displayed on the output unit 101. When information is input to items as indicated by reference signs a to e, the input information is controlled to be displayed on the screen indicated by reference sign f. Here, the stacking time interval calculation device 100 divides a frame as shown in FIG. 3 into a plurality of blocks by placing the casing in a plurality of layers in the height direction and a plurality of sections in the horizontal direction. The overlap time interval is calculated. Here, the case will be described assuming that it is a tunnel. As shown in the figure, the horizontal depth (span) of the casing is divided into a plurality of sections (three sections in the figure). Further, the vertical height of the housing is divided into a plurality of layers (five layers in the figure). In the present embodiment, concrete is placed for each block divided by such sections and layers.

  Returning to FIG. 1, the frame size input unit 102 includes a frame size including the thickness of a frame formed by stacking a plurality of blocks of concrete, the number of blocks in the vertical direction of the frame, and the height of each layer. Accept input. In FIG. 2, reference a1 indicates input items such as the thickness of the chassis (mounting thickness), the length and angle of each part of the chassis, and the number of layers (number of layers). The symbol f displays a cross-sectional view of the shape of the housing to be formed and a graphic showing each point defined in the housing. The frame size input unit 102 accepts values such as coordinates, length, and angle of each point input by the user in accordance with the graphic displayed on the screen indicated by the symbol f. Reference numeral a2 indicates an input item of height for each layer. The frame size input unit 102 receives the value of the height for each layer input to the item indicated by reference sign a2. The frame size input unit 102 stores each input information in its own storage area.

  Returning to FIG. 1, the section size input unit 103 receives input of the horizontal length (span length) of the casing to be formed and the number of blocks (span length (number of divisions)) in the horizontal direction of the casing. Reference numeral b in FIG. 2 indicates input items of the span length (m) and the span length (number of divisions). The partition dimension input unit 103 stores each input information in its own storage area.

  Returning to FIG. 1, the placement speed input unit 104 receives an input of a placement speed of a pump for placing concrete. In FIG. 2, input items such as a placement amount (placement speed) per 1 hour (hour) of the pump, a placement start time, and the number of pumps are shown. The placement speed input unit 104 stores the input information in its own storage area.

  Returning to FIG. 1, the placing order input unit 105 receives input of the placing order of concrete for each block. 2 indicates a table for inputting the placement order of each block according to the number of layers input to the code a1 and the span length (number of divisions) input to the code b. The placement order input unit 105 may accept an input of a number indicating the placement order for each block included in the table of the symbol d. For example, the placement order input unit 105 detects that a block portion has been clicked and detects it. Each time, the placement order may be entered in sequence at each location. The placing order input unit 105 stores the input information in its own storage area.

The concrete amount calculation unit 106 calculates the amount of concrete per block based on the thickness of the frame, the height of each layer, the length of the frame in the horizontal direction, and the number of sections. Here, the concrete amount calculation unit 106 first calculates a cross-sectional area for each block by a polygon formula. For example, the shape of the cross section of a specific block can be calculated as shown in FIG. By approximating such a cross section to a polygon as shown in FIG. 4B, and calculating the area of this polygon, the cross section of the concrete can be calculated. Here, for example, the calculation is performed using a polygon obtained by dividing the number of divisions per layer into 20 in the height direction. For example, assuming that the coordinates of n vertices in a polygon are (X _k , Y _k ), the area S is calculated by the following formula (1) which is a polygon formula.

  Further, the concrete amount calculation unit 106 can calculate the span direction distance for each block by (span length) / (number of sections). The concrete amount calculation unit 106 calculates the value of (cross-sectional area) × (span direction distance) as the amount of concrete (volume) per block. The concrete amount calculation unit 106 stores the calculated concrete amount for each block in its own storage area.

  The required time calculation unit 107 is placed per block based on the concrete amount per block calculated by the concrete amount calculation unit 106 and the pumping speed input to the driving speed input unit 104. Calculate the required time. The required time calculation unit 107 calculates the value of (concrete amount) / (setting speed) as the required setting time. The required time calculation unit 107 stores the calculated required driving time for each block in its own storage area.

  The overlapping time interval calculation unit 108 calculates the overlapping time interval between the block forming the casing and the other blocks in contact with the block based on the required time for placement and the placement order. Here, the overlapping time interval calculation unit 108 first calculates a value of (driving start time) + (required driving time) + (pump moving time) as a driving end time. Then, with the driving end time as the start time, the driving end time of the block whose placement order is next is calculated in the same manner. In this way, the overlapping time interval calculation unit 108 calculates the driving start time and the driving end time for each block. Then, the overlapping time interval calculation unit 108 calculates the difference between the driving end time of a specific block and the driving start time of another block in contact with the block as the overlapping time interval. Here, the overlap time interval calculation unit 108 calculates the overlap time interval with the ceiling portion of the tunnel as one block regardless of the number of sections in the span direction. The overlapping time interval calculation unit 108 stores the calculated overlapping time interval for each block in its own storage area.

  The output control unit 109 performs a calculation based on each information input to the overlapping time interval calculation device 100 and causes the output unit 101 to output an image. For example, the output control unit 109 causes the output unit 101 to output an image for sequentially displaying a plurality of blocks at the positions of the blocks in the frame in accordance with the placement order, as indicated by reference numeral f in FIG. Here, the screen is shown from the time when the block having the placement order of 1 to the block having the placement order of 20 from the block having the placement order of 1 to the block.

FIG. 6 shows a table created by the output control unit 109 on the output unit 101 based on the stacking time interval calculated by the stacking time interval calculation unit 108, the placement start time, the placement end time, and the like. An example of the displayed screen is shown. The symbol a is a table showing the stacking time interval for each section and for each layer. The code | symbol b is the table | surface in which the amount of concrete to lay, the laying start time, and the laying end time were shown for every division and every layer.
The output control unit 109 may process the information calculated by the overlap time interval calculation unit 108 into a file format such as a spreadsheet application and output a result file. For example, FIG. 7 is a diagram illustrating a data example of a result file generated by the overlapping time interval calculation unit 108. Here, information on the block and layer for each block, the driving start time, the driving end time, the stacking time interval of the same layer in the same layer, and the stacking time interval of the same layer in the same layer is shown. Has been.

  The determination unit 110 compares the threshold of the overlap time interval determined to the extent that no cold joint between the blocks is generated and the overlap time interval calculated by the overlap time interval calculation unit 108 to determine the overlap time. When the overlap time interval calculated by the interval calculation unit 108 exceeds the threshold, the output unit 101 is made to output a warning. The warning is, for example, a message indicating that the overlapping time interval exceeds the threshold value, or a block location where the overlapping time interval exceeds the threshold value or a numerical value of the overlapping time interval on the screen shown in FIG. Or output in red. Here, for example, the determination unit 110 can store a predetermined time (for example, 2 hours) in its own storage area in advance.

  Next, with reference to the drawings, an operation example of the overlapping time interval calculation apparatus 100 according to the present embodiment will be described. FIG. 8 is a flowchart illustrating an operation example in which the overlapping time interval calculation apparatus 100 calculates the overlapping time interval. The frame size input unit 102 receives input of the frame size including the thickness, length, angle, and the like of the frame, the number of layers, and the height of each layer (step S1). The partition dimension input unit 103 receives input of partition dimensions of the span length and the span length (number of divisions) (step S2). The driving speed input unit 104 receives input of the pump driving speed and driving start time (step S3). The placement order input unit 105 receives the pump movement time and the placement order for each block (step S4).

  The concrete amount calculation unit 106 calculates a cross-sectional area for each block using a polygon formula based on the thickness of the frame input to the frame size input unit 102, the height of each layer, and the frame size. The concrete amount calculation unit 106 calculates the concrete amount for each block by multiplying the calculated cross-sectional area of the block by the span direction distance according to the section (step S5). The required time calculation unit 107 calculates the required time for placement based on the concrete amount calculated in step S5 and the placement speed input in step S3 (step S6).

  Then, the driving time interval calculation unit 108 finishes driving based on the driving start time input in step S3, the driving required time calculated in step S6, and the pump movement time input in step S4. Time is calculated (step S7). Further, the overlapping time interval calculation unit 108 calculates the placement start time interval for each block based on the implantation start time and the implantation end time for each block (step S8). The output control unit 109 processes the driving end time and the placement start time interval calculated by the overlapping time interval calculation unit 108 into tabular data, and causes the output unit 101 to output a screen as shown in FIG. (Step S9). The determination unit 110 compares a predetermined threshold value with the overlap time interval (step S10). When determining unit 110 determines that the overlap time interval is greater than the threshold (step S10: YES), it causes output control unit 109 to output a warning (step S11). Then, returning to step S2, for example, to increase the number of blocks, the user increases the number of sections or the number of layers and inputs again, until the overlap time interval becomes a time interval that does not cause a cold joint. The overlapping time interval calculation apparatus 100 calculates the overlapping time interval. On the other hand, when the determination unit 110 determines in step S10 that the overlap time interval is smaller than the threshold (step S10: NO), the overlap time interval calculation device 100 ends the process.

  In the present embodiment, a predetermined value is stored in the storage area of the determination unit 110 as the threshold of the overlapping time interval determined to such an extent that a cold joint between blocks does not occur. You may make it receive the input of such a threshold value from a user. Alternatively, for example, information that associates a temperature condition, concrete strength, and the like with a threshold value of an allowable time interval at which a cold joint does not occur is stored in advance, and the temperature condition or concrete strength value is input in advance. The threshold value may be read out and used as a comparison value with the overlap time interval.

  As described above, according to the present invention, the concrete stacking time interval can be calculated for each placement block and displayed in an easy-to-understand manner. For example, when a value larger than a predetermined time interval at which the cold joint assumed by the installer does not occur is displayed by the stacking time interval calculation device 100 of the present embodiment, the concrete placement height, the placement order, When the concrete placement speed and the like are appropriately changed and input, the overlay time interval corresponding to the input information is immediately displayed. Even in the case of trial and error as described above, even if the input condition is changed, the result is immediately output, so that an appropriate concrete placement design image can be efficiently formulated.

  It should be noted that the program for realizing the function of the processing unit in the present invention is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read by the computer system and executed to execute the overlap time interval. May be calculated. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer system” includes a WWW system having a homepage providing environment (or display environment). The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” refers to a volatile memory (RAM) in a computer system that becomes a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those holding programs for a certain period of time are also included.

  The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

DESCRIPTION OF SYMBOLS 100 Overlay time interval calculation apparatus 101 Output part 102 Body size input part 103 Division dimension input part 104 Placing speed input part 105 Placing order input part 106 Concrete quantity calculation part 107 Required time calculation part 108 Overlay time interval calculation part 109 Output control unit 110 determination unit

Claims (6)

A frame size input unit that receives input of a frame size including the thickness of a frame formed by stacking concrete of a plurality of blocks, the number of layers of the block in the vertical direction of the frame, and the height of each layer,
A section size input unit that receives input of a length in a horizontal direction of the casing and a number of sections of the block in the horizontal direction of the casing;
A casting speed input unit for receiving input of a casting speed of a pump for placing the concrete;
A placing order input unit for receiving input of the placing order of the concrete for each block;
Based on the thickness of the frame, the height of each layer, the length of the frame in the horizontal direction, and the number of sections, a concrete amount calculation unit that calculates the amount of concrete per block,
A required time calculation unit for calculating a required time for placing per block based on the calculated amount of concrete per block and the speed of placing the pump;
Based on the placement required time and the placement order, a placement time interval calculation unit that calculates a placement time interval between the block and another block in contact with the block;
An output unit for outputting the overlapping time interval;
A device for calculating the overlap time interval. 2. The overlap time interval calculation according to claim 1, wherein the output unit outputs an image in which a plurality of the blocks are sequentially displayed at the positions of the blocks in the housing in accordance with the placement order. apparatus. The enclosure is a tunnel;
3. The stacking time interval calculation unit calculates the stacking time interval by setting the ceiling portion of the tunnel as one block regardless of the number of sections. 4. Overlap time interval calculation device. Calculated by the time interval calculation unit by comparing the threshold of the overlap time interval determined to the extent that the cold joint between the blocks does not occur and the overlap time interval calculated by the overlap time interval calculation unit 4. The overlap time interval calculation according to claim 1, further comprising: a determination unit that outputs a warning to the output unit when the overlap time interval that has been exceeded exceeds the threshold value. 5. apparatus. Receiving and storing the input of the frame size including the thickness of the frame formed by stacking a plurality of blocks of concrete, the number of layers of the block in the vertical direction of the frame, and the height of each layer;
Receiving and storing the input of the horizontal length of the housing and the number of sections of the block in the horizontal direction of the housing;
Receiving and storing an input of a casting speed of a pump for placing the concrete;
Receiving and storing an input of a concrete placement order for each block;
Calculating the amount of concrete per block based on the thickness of the housing, the height of each layer, the length of the housing in the horizontal direction, and the number of sections;
Calculating the time required for placing per block based on the calculated amount of concrete per block and the pumping speed of the pump;
Calculating an overlap time interval between the block and another block in contact with the block based on the required time for placement and the placement order;
Outputting the overlap time interval;
A method for calculating the overlap time interval. In the computer of the overlapping time interval calculation device,
Receiving and storing the input of the frame size including the thickness of the frame formed by stacking a plurality of blocks of concrete, the number of layers of the block in the vertical direction of the frame, and the height of each layer;
Receiving and storing the input of the horizontal length of the housing and the number of sections of the block in the horizontal direction of the housing;
Receiving and storing an input of a casting speed of a pump for placing the concrete;
Receiving and storing an input of a concrete placement order for each block;
Calculating the amount of concrete per block based on the thickness of the housing, the height of each layer, the length of the housing in the horizontal direction, and the number of sections;
Calculating the time required for placing per block based on the calculated amount of concrete per block and the pumping speed of the pump;
Calculating an overlap time interval between the block and another block in contact with the block based on the required time for placement and the placement order;
Outputting the overlap time interval;
Overlap time interval calculation program that executes

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