JP7265295B1 - Process control system - Google Patents

Abstract

Kind Code: A1 An object of the present invention is to provide a process management system that can easily grasp the progress of a process in accordance with the actual situation. The present invention for solving the above problems is a process management system X for managing the progress of a process, comprising a recording means 11 for recording a process P, an evaluation means 12 for evaluating the progress of the process P, and a display means 13, the recording means 11 stores the start time 321, the end time 322 of the process P, and the progress rate R1 for the entire process, and the evaluation means 12 acquires an arbitrary time. It has a time setting means 121 and a calculation means 122 for calculating a progress rate. A progress rate R2 is calculated, and the progress rate R is calculated by dividing the progress rate R1 by the period progress rate R2. The display means 13 displays the progress rate R and transmits the display processing result. [Selection drawing] Fig. 3

Description

Application of Article 30, Paragraph 2 of the Patent Act Published on the following web page on March 3, 2022 https://kolcx. com/, https://prtimes. jp/main/html/rd/p/000000003.000081365. html, https://kolcx. com/feature/timeliner/

The present invention relates to a system for facilitating grasping of the progress of a process at a construction site such as construction.

Process management is extremely important in carrying out construction plans or construction plans at large-scale construction sites. is delayed. In order to solve such problems, for example, Patent Document 1 discloses a process management system that allows a manager to grasp the process by displaying work items that cannot be performed according to the process together with 3D shape data. is described.

JP-A-2001-262829

In the invention described in Patent Document 1, etc., as a means of managing the progress of the construction work process, a method of grasping how much the process has progressed in the overall process is used.

However, in order to accurately grasp the actual progress, it is preferable to grasp how far the actual process has progressed compared to the actual time, and distribute the work etc. accordingly.

SUMMARY OF THE INVENTION In view of the above problems, it is an object of the present invention to provide a process control system that can easily grasp the progress of a process according to the actual situation.

The present invention for solving the above problems is a process management system for managing the progress of a process, wherein the process management system includes recording means for recording the process, evaluation means for evaluating the progress of the process, and information display means for performing display processing, wherein the recording means stores the start time of the process, the end time of the process, and the degree of progress of the process as a whole, and the evaluation means stores any time and calculation means for calculating a progress rate, wherein the calculation means calculates the ratio of the period from the start time to the arbitrary time to the period from the start time to the end time A process management system that calculates the degree of progress of the period, calculates the progress rate by dividing the degree of progress by the degree of progress of the period, and the display means performs display processing of the progress rate and transmits the display processing result be.
With such a configuration, it is possible to easily grasp the progress in accordance with the actual situation.

In a preferred embodiment of the present invention, the display means performs display processing on a progress display area for displaying progress, and the progress display area includes a time axis representing time and a position corresponding to the start time on the time axis. and displaying a belt-shaped body extending to a position corresponding to the end time so as to be parallel to the time axis.
Such a configuration makes it easy to visually grasp the progress.

In a preferred embodiment of the present invention, the display means performs a display process of distributing two or more colors to the strip, and a display process of changing the distribution according to the degree of progress.
Such a configuration makes it easy to visually grasp the progress.

In a preferred embodiment of the present invention, the display means displays a slide axis extending vertically from the time axis, and the time setting means obtains the arbitrary time by operating the slide axis.
With such a configuration, the user can grasp the progress rate in the past or the future by intuitive operation and take measures accordingly.

In a preferred embodiment of the present invention, the recording means stores the three-dimensional object in association with the process, the display means displays a model display area for displaying the three-dimensional object, and the three-dimensional object is , is displayed in a color corresponding to the progress rate associated with the process.
With such a configuration, the user can easily grasp which process related to the three-dimensional object is delayed.

In a preferred form of the present invention, the display means can transparently display a three-dimensional object.
With such a configuration, it is possible to easily grasp the situation of the equipment that does not appear on the outside.

The present invention for solving the above-mentioned problems is a management program for managing the progress of a process, the management program comprising an information processing apparatus, recording means for recording the process, and evaluation means for evaluating the progress of the process. , the recording means stores the start time of the process, the end time of the process, and the progress of the process as a whole, and the evaluation means is an arbitrary and calculation means for calculating a progress rate, wherein the calculation means determines the period from the start time to the arbitrary time for the period from the start time to the end time A management program that calculates a degree of elapsed time that is a ratio of , calculates a progress rate by dividing the degree of progress by the degree of elapsed time, and that the display means performs display processing on the progress rate and transmits a display processing result is.
With such a management program, it is possible to easily grasp the progress in accordance with the actual situation.

The present invention for solving the above problems is a management method for managing the progress of a process, wherein a process management system includes a recording step for recording the process, an evaluation step for evaluating the progress of the process, and an information display process. the recording step storing the start time of the process, the end time of the process, and the progress of the process as a whole; and the evaluation step storing an arbitrary time. and a calculation step of calculating a progress rate, wherein in the calculation step, the ratio of the period from the start time to the arbitrary time to the period from the start time to the end time calculating the degree of elapsed period, calculating the progress rate by dividing the degree of progress by the degree of elapsed period, and performing display processing of the progress rate in the display step, and transmitting the display processing result. It is a management method for managing progress.
With such a management method, it is possible to easily grasp the progress in accordance with the actual situation.

The present invention, which solves the above problems, can provide a process management system that can easily grasp the progress of a process in accordance with the actual situation.

1 is a block diagram showing a system configuration according to an embodiment of the present invention; FIG. 1 is a hardware configuration diagram according to an embodiment of the present invention; FIG. It is a figure which shows the system configuration|structure based on embodiment of this invention. 1 is a functional block diagram of an information processing device according to an embodiment of the present invention; FIG. 1 is a configuration diagram of a database of an information processing device according to an embodiment of the present invention; FIG. 4 is a flow chart of an information processing device according to an embodiment of the present invention; FIG. 4 is a diagram showing an example of a display screen according to the embodiment of the present invention; FIG. FIG. 4 is a schematic diagram of a progress display area, according to an embodiment of the present invention;

Hereinafter, a process control system for progress of processes according to each embodiment of the present invention will be described with reference to the drawings. The description will be detailed in the order of the configuration of the embodiment, the method of implementation, and another example. In addition, each embodiment shown below is an example of this invention, and does not limit this invention to each following embodiment.

For example, although the configuration, operation, and the like of the process control system X will be described in the present embodiment, similar effects can be achieved by methods, devices, computer programs, and the like that are executed. The program in this embodiment may be provided as a computer-readable non-transitory recording medium, may be provided as a downloadable form from an external server, or may be provided as a downloadable program from an external server. Alternatively, the program may be started on an external computer immediately.

Further, in the present embodiment, "means" may include, for example, a combination of hardware resources implemented by circuits in a broad sense and software information processing that can be specifically realized by these hardware resources. In this embodiment, "information" is represented by, for example, the physical value of a signal value representing voltage or current, or the height of a signal value as a binary bit aggregate composed of 0 or 1, and is broadly defined. Communications and operations may be performed on the circuit. A circuit in a broad sense is a circuit realized by appropriately combining circuits, circuits, processors, memories, and the like. That is, it includes CPU (Central Processing Unit), GPU (Graphics Processing Unit), LSI (Large Scale Integration), ASIC (Application Specific Integrated Circuit), FPGA (Field-Programmable Gate Array), and the like.

The process management system X mainly manages a plan PJ for construction of a large-scale construction site, and the plan PJ includes a plurality of processes P. In order to carry out the plan PJ, a plurality of processes P must be performed in a predetermined order.

<System configuration>
FIG. 1 is a block diagram showing the system configuration of the process control system X. As shown in FIG.
The process control system X includes an information processing device 1 that operates as a server and a terminal device 2 . The information processing device 1 and the terminal device 2 are provided so as to be able to communicate with each other through the network NW.

The network NW is a network bus in this embodiment. The network NW may include, for example, an IP (Internet Protocol) network. There is no limit to the type of communication protocol in the network NW, and there is no limit to the type and scale of the network.

A general-purpose personal computer, a smart phone, a tablet terminal, or the like can be used as the terminal device 2 . A computer for a server or the like may be used as the information processing device 1, and information processing described later is realized by transmitting and receiving information via the terminal device 2 as a client terminal. It is also possible to configure the information processing apparatus 1 using a plurality of computers.

<Hardware configuration>
FIG. 2 is a hardware configuration diagram of the information processing device 1 and the terminal device 2. As shown in FIG. FIG. 2A is a diagram showing an example of the hardware configuration of the information processing device 1. As shown in FIG. The information processing apparatus 1 includes a processing unit 101, a storage unit 102, and a communication unit 103 as a hardware configuration.

In the information processing apparatus 1, the processing unit 101 includes one or more processors such as a CPU, and executes the management program 10 and other applications to control the overall operation processing. The storage unit 102 is an HDD, ROM, RAM, or the like, and stores various data used in the management program 10 and the process management system X according to the present invention. The communication unit 103 performs communication control with the network NW, inputs necessary for operating the information processing apparatus 1, and outputs related to operation results.

The processing unit 101 of the information processing apparatus 1 implements a functional configuration, which will be described later, by executing processing based on the management program 10 stored in the storage unit 102 .

The storage unit 102 stores various information related to the process. In this embodiment, the storage unit 102 includes a plan management list DB 31, a process management list DB 32, and a three-dimensional model DB 33 for data management.
These DBs and related information may be stored in different storage media such as the storage unit 202 of the terminal device 2, or may be stored in a plurality of storage media and synchronized via the network NW.

FIG. 2B is a diagram showing an example of the hardware configuration of the terminal device 2. As shown in FIG. The terminal device 2 includes a processing unit 201, a storage unit 202, a communication unit 203, an input unit 204, and an output unit 205 as a hardware configuration.

The processing unit 201 of the terminal device 2 includes one or more processors such as a CPU, and controls the overall operation processing of the terminal device 2 by executing an OS, browser software, and other applications. The storage unit 202 of the terminal device 2 is a HDD, ROM, RAM, or the like, and stores an OS, browser software, and data used when the processing unit 201 executes processing based on a program. The communication unit 203 of the terminal device 2 performs communication control with the network NW, inputs to the information processing device 1, and outputs related to operation results. The input unit 204 of the terminal device 2 is a touch panel, a mouse, a keyboard, or the like, and inputs an operation request from the user to the processing unit 201 . The output unit 205 of the terminal device 2 is a display or the like, and displays the results of the display processing performed by the processing unit 201 .

In addition, as shown in FIG. 3, the terminal device 2 is a design manager terminal device 2A used by the designer of the plan PJ, an orderer terminal device 2B used by the orderer of the plan PJ, and executes the process P The functional means that can be performed in each terminal device 2 are different.

<Functions of information processing device>
FIG. 4 is a functional block diagram of the information processing device 1. As shown in FIG. The information processing apparatus 1 includes recording means 11, evaluation means 12, and display means 13 as functional means. By these means, information processing by software (stored in storage unit 102) is specifically realized by hardware (processing unit 101, etc.).

FIG. 5 is a diagram showing an example of information stored in the storage unit 102. As shown in FIG. In this embodiment, the storage unit 102 has a plan management list DB 31 that stores plan information, a process management list DB 32 that stores process information, and a 3D model DB 33 that stores 3D model information.

The recording means 11 is a means for receiving various information from the terminal device 2 and recording it in the storage section 102 of the information processing device 1 . The various information referred to here includes information related to the management of the process P, 3D models related to design, manuals related to design, and information on materials and fixtures.

In this embodiment, the recording means 11 receives various information about the plan from the design manager terminal device 2A or the orderer terminal device 2B, and records it in the storage section 102 of the information processing device 1 as plan information. The plan management list DB 31 stores plan information. As shown in FIG. 5A, the plan information includes a plan ID assigned to each plan PJ, the name of the plan PJ, the period of the plan PJ, the ID of the 3D model related to the plan PJ, the storage location of the 3D model, the plan It has the creation date and time of the project, the name of the orderer, etc.

Further, in this embodiment, the recording means 11 receives various information related to the process from the design manager terminal device 2A, the orderer terminal device 2B, or the builder terminal device 2C, and stores the information in the information processing device 1 as process information. Record in section 102 . The process management list DB 32 stores process information. As shown in FIG. 5B, the process information includes a process ID assigned to each process P, a plan ID related to the process P, the name of the process P, the order in which the process P is performed, the start time 321 of the process P, and the process It has the end time 322 of P, the ID of the 3D object corresponding to the process P, and the degree of progress R1 of the process P. The process information further records the name of the person in charge of the process P, the name of the person who participates in the process P, the storage location of the data of recorded photographs, the storage location of the manual about the process, the status of materials required for the process P, and special notes. etc.

In this case, the recording means 11, in addition to the 3D data related to the construction work, transmits the start time 321 of the process P, the end time 322 of the process P, and the degree of progress of the process P as a whole through the design manager terminal device 2A. The record of R1 can be accepted. As a result, the start time 321 and end time 322 of the process P can be changed according to the progress.

Furthermore, the recording means 11 can receive records of the start time 321 of the process P, the end time 322 of the process P, and the progress rate R1 for the entire process P via the orderer terminal device 2B.

Furthermore, the recording means 11 can receive the progress rate R1 and the recording of information related thereto via the builder terminal device 2C. The information includes recorded photographs related to the degree of progress R1 and matters to be noted.

Further, in this embodiment, the recording means 11 receives various information about the three-dimensional model from the design manager terminal device 2A, and records it in the storage section 102 of the information processing apparatus 1 as three-dimensional model information. The three-dimensional model information has, as shown in FIG. 5(c), the ID of the three-dimensional object, the ID of the 3D model including the three-dimensional object, and the ID of the process P related to the three-dimensional object. A three-dimensional model in the present invention is three-dimensional data of a completed image of a plan PJ for construction, and is made up of a combination of three-dimensional objects for individual facilities.
A plurality of objects may be associated with the same process ID in the three-dimensional object, and a plurality of processes may be associated with one three-dimensional object.

The evaluation means 12 processes the information recorded by the recording means 11 and calculates the progress rate R. FIG. The evaluation means 12 has a timing setting means 121 for acquiring an arbitrary timing 323 set by the user and a calculating means 122 for calculating the progress rate R based on the arbitrary timing 323 .

Note that the progress rate R in the present invention is a progress rate proportionally divided according to an arbitrary time. The calculating means 122 calculates a period elapsed degree R2, which is the ratio of the period from the start time 321 to an arbitrary time 323 set by the user to the period from the start time 321 to the end time 322 . Further, it is calculated by dividing the degree of progress R1 by the degree of elapsed period R2.

The display means 13 performs display processing of various screens for user operation input, and transmits the display processing result to the terminal device 2 via the network NW. That is, the display means 13 displays the information recorded in the recording means 11 and the information obtained by the evaluation means 12 as information on the process P. FIG. At this time, the process P and the 3D object corresponding to the process P are displayed.

The process control method using the process control system X and the details of processing by each functional means element will be described below. FIG. 6 is a flow chart showing a procedure from storing information in the storage unit 102 to displaying it on the output unit 205. As shown in FIG.

In advance, as a recording step for managing the progress of the process, the recording means 11 of the information processing device 1 records the process information and the 3D model information in the storage unit 202 of the information processing device 1 . Also, changes in the information related to the process P (the start time 321, the end time 322, the degree of progress R1, etc.) are also recorded in the storage unit 202. FIG.

In step S<b>1 , a display request from the user is accepted via the terminal device 2 .

Thereafter, in step S2, as an evaluation step for evaluating the progress of the process P, the evaluation means 12 calculates a progress rate R. At this time, the timing setting means 121 obtains the arbitrary timing 323 as a timing setting step for obtaining the arbitrary timing. The time setting means 121 acquires the current date and time from the processing unit 101 and acquires it as an arbitrary time. For example, at the stage of receiving the display request, the time setting means 121 acquires the current date and time as an arbitrary time, and the calculation means 122 calculates the progress rate R based on it.

After that, in step S2, as a calculation step for calculating the progress rate, the calculation means 122 calculates the proportionally divided progress rate R by performing the following processing.
First, the calculation means 122 acquires the start time 321, the end time 322, and the degree of progress R1 from the process control list DB32. Next, by calculating the difference between the end time 322 and the start time 321, the period from the start time 321 to the end time 322 (work period t1) is calculated. Furthermore, by calculating the difference between the arbitrary timing 323 and the starting timing 321, the elapsed time (elapsed time t2) from the starting timing 321 to the arbitrary timing 323 is calculated. After that, by dividing the elapsed time t2 by the work period t1, a period elapsed degree R2, which is a ratio representing how much time has elapsed with respect to the work period, is calculated.
Then, the calculating means 122 calculates the proportionally divided progress rate R by dividing the progress rate R1 by the period elapsed rate R2.
If the elapsed time t2 exceeds the work period t1, exception processing is performed with the period elapsed degree R2 set to "1". That is, it represents a state in which the period has already passed. Further, when the elapsed time t2 is 0 or takes a negative value, exception processing is performed in which the period elapsed degree R2 is not calculated and the progress rate R is not calculated.

For example, the calculating means 122 can perform the apportionment processing only for the steps in which the position of the slide shaft 413 is between the start time 321 and the end time 322 . In this case, the calculating means 122 performs exceptional processing by setting the period elapsed degree R2 to "1" for the process whose end time 322 is past the slide axis. Furthermore, the calculation means 122 acquires all processes whose start times 321 are in the past with respect to the position of the slide axis, thereby excluding processes that do not require progress rate calculation.

Next, in step S3, as a display step for displaying information, the display unit 13 performs display processing on a display screen for displaying process information, progress rate R, and data of the three-dimensional object, and transmits the display processing result. As shown in FIG. 7, the display screen has a progress display area 41 and a model display area 42 . The elements displayed in each area are described in detail below.

In the progress display area 41, a time axis 411 representing time, a strip 412 representing each process P associated with the process control list DB 32, and a slide axis 413 displaying an arbitrary time 323 set by the user. and contains elements of

The time axis 411 is an axis line arranged so as to be horizontal with one side of the outer frame of the rectangular display screen 40. In the present embodiment, the time axis 411 is located at the center position of the display screen 40, which is horizontal with the lower side, from the left. It shows how time flows to the right. Numerical sequences representing dates or times are arranged at regular intervals near the time axis 411 , and the numerical sequences correspond to the start time 321 and end time 322 .
It is preferable that a plurality of thin lines perpendicular to the time axis 411 extend on the time axis 411 corresponding to the intervals of the numerical sequence, thereby representing the strip 412 to be displayed at a location away from the time axis 411. Clarify the time display.

As shown in FIG. 8, the strip 412 is a rectangular parallelepiped display provided horizontally with the time axis 411, and simultaneously represents the start time 321, the end time 322, and the degree of progress R1 of one process. Specifically, one end of strip 412 represents start time 321 and the other end represents end time 322 .
That is, one side of the strip 412 is a line segment on a line drawn vertically from a point on the time axis 411 at the time corresponding to the start time 321 . Also, one side of the band-shaped body 412 opposite to the side is a line segment on a line drawn vertically from a point at the time corresponding to the end time 322 .
A strip 412 connecting the endpoints of these line segments is displayed at an appropriate position in the progress display area 41 .

Strip 412 is treated such that it has more than one color distribution. In this embodiment, dark colors and bright colors are distributed and displayed. As for the distribution, the strip 412 is displayed in such a manner that one end of the strip 412 is filled with a different color in proportion to the progress rate R1 with respect to the entire length in the direction of the time axis 411 .

A plurality of band-shaped bodies 412 are arranged in the order of the IDs to which the process P is assigned (or in the order of the "process order") in the direction away from the time axis 411 .
Further, the progress rate R of the process P represented by the strip 412 is displayed adjacent to the strip 412 . The progress rate R is preferably arranged in the advancing direction of the time axis.

The slide axis 413 is an axis extending perpendicularly from the time axis 411 and is displayed with a length that penetrates all the strips 412 that are arranged and displayed. Above the time axis 411 near the slide axis 413, an arbitrary time 323 set by the time setting means 121 is displayed.

The model display area 42 is a place where the 3D model stored in the 3D model DB 34 is displayed.
In the 3D model of this embodiment, all objects are subjected to transparency processing or wireframe display processing so that the internal conditions of the facility can be viewed at a glance.
It should be noted that the object to be displayed in the model display area 42 may be opaque so that the appearance can be grasped at a glance. configured to be

In step S4, it is detected that the slide shaft 413 has been operated. In this embodiment, the timing setting means 121 acquires an arbitrary timing 323 by operating the slide shaft 413 . Since the slide axis 413 can be dragged in the direction of the time axis 411 by the input unit 204, the arbitrary timing 323 can be intuitively changed.
That is, when the slide axis 413 is operated (YES in step S4), the calculating means 122 calculates the progress rate R based on the arbitrary timing 323 newly acquired by the timing setting means 121 (step S2), the calculated progress rate R is displayed at a place adjacent to the strip 412 (step S3).

In step S5, it is detected that the strip 412 has been operated. In this embodiment, the recording unit 11 acquires the start time 321 and the end time 322 by operating the band 412 . The length of the strip 412 can be changed by dragging the end of the strip 412 using the input unit 204 , and the position of the strip 412 can be changed by dragging in the direction of the time axis 411 . Since it is possible to change the whole, the start time 321 and the end time 322 can be changed intuitively.
That is, when the strip 412 is operated (YES in step S5), the calculation means 122 calculates the progress rate R based on the start time 321 and the end time 322 newly acquired by the recording means 11. (Step S2), the calculated progress rate R is displayed at a place adjacent to the strip 412 (Step S3).

The display means 13 is configured to be able to receive a selection for an arbitrary process P. That is, by selecting a strip 412 displayed in the progress display area 41, the process information (information on the person in charge, materials, etc.) related to the strip 412 can be displayed at a predetermined position on the display screen 40. there is

Among the 3D objects linked to the selected process P, those that are displayed in the model display area 42 are colored in an opaque color. At this time, the 3D object is color-coded according to the progress rate associated with the 3D object.

The display means 13 may be configured so that a plurality of processes P can be selected. Also, depending on the position of the slide shaft 413, a process P that includes an arbitrary period 323 within the construction period t1 may be configured to be selectable.

FIG. 7 shows how the progress display area 41 and the model display area 42 are displayed in association with each other based on the process management list DB 32 and the three-dimensional model DB. Here, strip 412A and strip 412B are selected.
Since the strip 412A has a progress rate of 100%, the display means 13 displays the model display area 42 by coloring the object associated with the strip 412A in red.
On the other hand, since the progress rate of the strip 412B has not reached 100%, the display unit 13 displays the model of the object associated with the strip 412B in yellow, which is different from the color of the progress rate of 100%. Display processing is performed on the area 42 .
Also, those whose start time 321 of the associated process P is later than the arbitrary time 323, such as the band 412C, are not selected and are displayed in the model display area 42 as transparent wire frames. It is processed.

In addition, the display means 13 is arranged to extract the processes P whose progress rate R is below a certain level from the plan PJ, so that the processes P extracted by the extraction can be collectively selected. As a result, it is possible to extract delay points in the process that is currently being started, and to facilitate grasping of the progress of the plan PJ by the executor or the manager.

Further, the information stored in the storage unit 102 is configured to be arbitrarily changed by an authorized person using the information processing apparatus 1 . As a result, the users of the design manager terminal device 2A and the orderer terminal device 2B who have grasped the process can change the process P according to the progress.

X Process control system 1 Information processing device 10 Management program 101 Processing unit 102 Storage unit 103 Communication unit 11 Recording unit 12 Evaluation unit 121 Time setting unit 122 Calculation unit 13 Display unit 2 Terminal device 201 Processing unit 202 Storage unit 203 Communication unit 204 Input Unit 205 Output unit 31 Plan management list DB
32 Process control list DB
321 start time 322 end time 323 arbitrary time 33 three-dimensional model DB
40 Display screen 41 Progress display area 411 Time axis 412 Strip 413 Slide axis 42 Model display area PJ Plan P Process R Progress rate R1 Progress rate R2 Period elapsed rate

Claims (8)

A process control system for managing the progress of a process,
The process management system comprises recording means for recording the process, evaluation means for evaluating the progress of the process, and display means for displaying information,
Operated by a plurality of information terminals including at least a design manager terminal device and a builder terminal device,
The recording means stores the start time of the process, the end time of the process, and the progress of the process as a whole,
The recording means is provided so as to be able to receive records of the start time and the end time via the design manager terminal device, and further to be able to receive the record of the degree of progress via the builder terminal device. be
The evaluation means has time setting means for acquiring an arbitrary time and calculation means for calculating a progress rate,
The calculation means calculates a period lapse degree that is a ratio of the period from the start time to the arbitrary time to the period from the start time to the end time,
Calculate the progress rate obtained by dividing the latest degree of progress by the degree of elapsed time,
A process control system in which the display means displays the progress rate as a numerical value and transmits the result of display processing. The display means displays a progress display area for displaying progress,
The progress display area includes a time axis representing time,
2. The process according to claim 1, further comprising: performing display processing for displaying a belt-shaped body extending from a position corresponding to the start time to a position corresponding to the end time on the time axis so as to be parallel to the time axis. management system. The display means performs display processing for distributing two or more colors to the strip;
3. The process control system according to claim 2, further comprising a display process for changing the allocation according to the degree of progress. The display means displays a slide axis extending vertically from the time axis,
3. The process control system according to claim 2, wherein said time setting means acquires said arbitrary time by operating said slide axis. The recording means stores the three-dimensional object in association with the process,
The display means performs display processing on a model display area for displaying the three-dimensional object,
5. The process management system according to any one of claims 1 to 4, wherein the three-dimensional object is displayed in a color corresponding to the progress rate associated with the process. 6. The process control system according to claim 5, wherein said display means transparently displays said three-dimensional object. A management program for managing the progress of a process,
Operated by a plurality of information terminals including at least a design manager terminal device and a builder terminal device,
The management program causes the information processing device to function as recording means for recording the process, evaluation means for evaluating the progress of the process, and display means for displaying information,
The recording means stores the start time of the process, the end time of the process, and the progress of the process as a whole,
The recording means is provided so as to be able to receive records of the start time and the end time via the design manager terminal device, and further to be able to receive the record of the degree of progress via the builder terminal device. be
The evaluation means has time setting means for acquiring an arbitrary time and calculation means for calculating a progress rate,
The calculation means calculates a period lapse degree that is a ratio of the period from the start time to the arbitrary time to the period from the start time to the end time,
Calculate the progress rate obtained by dividing the latest degree of progress by the degree of elapsed time,
A management program in which the display means displays the progress rate as a numerical value and transmits a display processing result. A management method for managing the progress of a process,
Using a plurality of information terminals including at least a design manager terminal device and a builder terminal device,
A process control system executes a recording step of recording the process, an evaluation step of evaluating the progress of the process, and a display step of displaying information,
in the recording step, storing the start time of the process, the end time of the process, and the progress of the process as a whole;
In the recording step, the design manager terminal device can receive records of the start time and the end time, and the builder terminal device can receive records of the degree of progress,
The evaluation step includes a time setting step of obtaining an arbitrary time and a calculation step of calculating a progress rate,
In the calculating step, calculating a period lapse degree that is a ratio of the period from the start time to the arbitrary time to the period from the start time to the end time,
Calculate the progress rate obtained by dividing the latest degree of progress by the degree of elapsed time,
In the display step, display processing is performed on the progress rate as a numerical value, and the display processing result is transmitted.
A management method for managing the progress of the steps.

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